A human homologue of mouse Mater, a maternal effect gene essential for early embryonic development

doi:10.1093/humrep/17.4.903

This Article

	Abstract
	FREE Full Text (PDF )
	Submit a response
	Alert me when this article is cited
	Alert me when eLetters are posted
	Alert me if a correction is posted

Services

	Email this article to a friend
	Similar articles in this journal
	Similar articles in ISI Web of Science
	Similar articles in PubMed
	Alert me to new issues of the journal
	Add to My Personal Archive
	Download to citation manager
	Search for citing articles in: ISI Web of Science (37)
	Request Permissions

Google Scholar

	Articles by Tong, Z.-B.
	Articles by Nelson, L. M.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Tong, Z.-B.
	Articles by Nelson, L. M.

Social Bookmarking

	What's this?

Human Reproduction, Vol. 17, No. 4, 903-911, April 2002
© 2002 European Society of Human Reproduction and Embryology

A human homologue of mouse Mater, a maternal effect gene essential for early embryonic development

Zhi-Bin Tong^,1, Carolyn A. Bondy, Jian Zhou and Lawrence M. Nelson

Developmental Endocrinology Branch, NICHD, National Institutes of Health, Bethesda, MD 20892, USA

Abstract

Top
Abstract
Introduction
Materials and methods
Results
Discussion
Acknowledgements
References

BACKGROUND: Mater is a maternal effect gene required for earlyembryonic development in mice, and its protein serves as anautoantigen in a mouse model of autoimmune premature ovarianfailure. METHODS: Human MATER cDNA was cloned by PCR techniques.The mRNA and protein were determined using hybridization andimmunodetection respectively. The cDNA and protein sequenceswere analysed using bioinformatics software. RESULTS: HumanMATER gene spans a ~63 kbp DNA at chromosome 19 and is composedof 15 exons and 14 introns. Expression of its mRNA (~4.2 kb)is restricted to the oocytes. Human MATER cDNA (3885 nt) showsan open reading frame (3600 nt) encoding a polypeptide chaincomposed of 1200 residues with a predicted molecular mass of134 236 Da. MATER protein (~134 kDa) was detected in human oocytes.The human and mouse cDNA share 67% homology while their deducedpolypeptide chains have 53% identity of amino acids. Also, theirprotein structures have a number of similar features. CONCLUSIONS:The human MATER and mouse Mater genes and proteins are conserved.Characterization of the human MATER and its protein providesa basis for investigating their clinical implications in autoimmunepremature ovarian failure and infertility in women.

Key words: embryo/infertility/MATER/oocyte/premature ovarian failure

Introduction

Top
Abstract
Introduction
Materials and methods
Results
Discussion
Acknowledgements
References

MATER is a maternal oocyte protein essential for normal earlyembryonic development beyond the 2-cell stage in mice (Tonget al., 2000a). MATER was initially identified as an oocyte-specificautoantigen associated with autoimmune oophoritis in mice (Tongand Nelson, 1999). The primary structure of mouse MATER, deducedfrom a cloned cDNA, is composed of 1111 amino acids with a molecularmass of 125 kDa. At the genomic level, Mater spans a ~32 kbDNA at the proximal end of the mouse chromosome 7 and contains15 exons (Tong et al., 2000b). Mater is transcribed specificallyin oocytes as oogenesis proceeds and the transcripts are degradedupon oocyte maturation and ovulation. As a maternal product,MATER accumulates during oogenesis and persists during embryogenesis.We have shown that Mater null female mice are sterile, yet theyexhibit normal oogenesis, ovarian development, oocyte maturation,ovulation and fertilization (Tong et al., 2000a). The null maleshave normal fertility. Furthermore, development of the embryosfrom Mater null females exhibits arrest at the 2-cell stage,a critical stage for embryonic genome activation in mice. Thus,Mater is a maternal effect gene essential for early embryonicdevelopment in mice.

It is known that maternal factors govern early embryonic developmentbefore embryonic genome activation takes place (Latham, 1999;Latham and Schultz, 2001) The maternal effect on early embryogenesisof Drosophila and Xenopus has been demonstrated by the identificationof a number of maternal effect genes (Akam, 1987; Droin, 1992).However, the presence and importance of maternal effect genesin early mammalian development has been only inferred untilthe recent identification of maternal effect genes in mice,such as Mater (Tong et al., 2000a) and Hsf1 (Christians et al.,2000). In addition, a maternal effect in early mammalian embryogenesishas been demonstrated recently for some well-known proteinssuch as zona pellucida proteins (Rankin et al., 2000, 2001)and E-cadherin (Larue et al., 1994), although their effectsare not restricted to embryonic development. To date, littleis known about the mechanisms by which maternal products directearly development in mammals. In mice, oocytes are transcriptionallyactive during oogenesis. As oocytes undergo growth and maturation,maternal proteins accumulate within the oocytes (Schultz, 1993).After fertilization, activation of the embryonic genome is anessential event in early development (Flach et al., 1982; Conoveret al., 1991; Bellier et al., 1997). In mice the zygotic genomeactivation begins in the late stage of 1-cell zygotes and becomesdominant at the 2-cell stage of embryos (Latham et al., 1991a,b;Bouniol et al., 1995; Nothias et al., 1995; Aoki et al., 1997).Metabolic inhibition of embryonic transcription does not blockthe first embryonic cleavage, but arrests development at the2-cell stage in mice (Warner and Versteegh, 1974; Flach et al.,1982). This suggests that maternal products direct developmentbefore the embryo undergoes genome activation, while the productsderived from embryonic genome are required for embryonic progressionbeyond the 2-cell stage. Although the molecular basis for thisprogrammatic transition is poorly understood, clearly the maternalproducts are required to constitute appropriate conditions foractivation of the embryonic genome.

In this study, we characterize human MATER gene and its protein.MATER serves as an autoantigen in mouse autoimmune oophoritis(Tong and Nelson, 1999), a model for human autoimmune prematureovarian failure (Kalantaridou and Nelson, 1998). We are on apath to determine whether human MATER plays an antigenic rolein the autoimmune pathogenesis of clinical premature ovarianfailure. In addition, MATER as a maternal factor supports earlyembryonic development in mice, through which it determines femalefertility (Tong et al., 2000a). This raises the possibilitythat a MATER gene mutation or MATER protein deficiency mightcause infertility in some women with normal ovulatory function.Thus, characterization of human MATER gene and its protein providesa new determinant with which to investigate ovarian autoimmunityand unexplained infertility in women.

Materials and methods

Top
Abstract
Introduction
Materials and methods
Results
Discussion
Acknowledgements
References

Cloning of the human MATER cDNA
A database of the human htgs (High Through Genomic Sequence)was blasted with the mouse MATER cDNA sequence to search forhuman homologous sequences (http://www.ncbi.nlm.nih.gov). Basedon DNA sequences of human chromosome 19 homologous to the mouseMATER cDNA, we designed oligonucleotides as primers for PCRreactions to amplify cDNA from a human ovarian cDNA library(Clontech, Inc., Palo Alto, CA, USA) and human ovarian cDNA(Invitrogen, Inc., Carlsbad, CA, USA; Origene Inc., Rockville,MD, USA). The PCR-cloned human cDNA was labelled with ³²P asa probe to screen the human ovarian cDNA library, as reportedpreviously (Tong and Nelson, 1999).

Determination of human MATER locus and exon-intron map
Using the sequence of cloned human MATER cDNA, one human genomicclone (GenBank accession: AC011470) was determined to carryan entire gene locus of human MATER. Nearly full-length humanMATER cDNA sequence was blasted to the DNA sequence of thishuman genomic clone to determine the size and numbers of exonsand introns. The AG–exon–GT rule was applied todetermine a splicing site between exon and intron (Breathnachand Chambon, 1981).

Northern and Southern hybridizations
Human ovarian total RNA from a 19 year old woman was obtainedunder an IRB-approved protocol (McGill University, Montreal,Canada) and our use of it was approved by the NIH Office ofHuman Subjects Research. Ovarian RNA from a 26 year old womanwas purchased from BioChain Inc. (Hayward, CA, USA). Separationof human ovarian total RNA (10 µg) was performed by 1%agarose/formaldehyde gel electrophoresis. The RNA was transferredonto a nitrocellulose membrane to prepare a Northern blot. ThePCR products were separated by 2% agarose gel electrophoresisand transferred onto a nylon membrane to prepare a Southernblot. Human MATER cDNA (~0.5 kbp) was labelled with ${alpha}$ -[³²P]dCTP(3000 Ci/mmol; ICN, Costa Mesa, CA, USA) using Ready-To-Go DNAdCTP Beads (Pharmacia, Inc., Piscataway, NJ, USA). Both RNAand DNA blots were hybridized (68°C, 2 h) with ³²P-labelledcDNA probe (~0.5 kbp) in QuikHyb solution (Stratagene, La Jolla,CA, USA). After washing the blots with a solution of 0.1xstandardsaline citrate/0.1% sodium dodecyl sulphate (SDS) at 65°C,the hybridization signals were detected by autoradiography.

PCR
Human ovarian cDNA (Invitrogen; Origene), human ovarian cDNAlibrary (Clontech) and the Human Rapid-Scan Gene ExpressionPanel (Origene) were used as templates for PCR reactions permanufacturers' instructions. Taq DNA polymerase (Life Technologies,Rockville, MD, USA) was used to amplify DNA products expectedwithin 1.5 kbp at a condition of the PCR reaction (95°C,5 min; 35 cycles of 95°C, 1 min; 60°C, 1 min; 72°C,2 min; and 72°C, 10 min for further extention). PlatinumPCR SuperMix (Life Technologies) was used for amplificationof DNA products (2–5 kbp) with prolonging extension timeat 72°C in every cycle, according to the product's manual.The PCR products were electrophoresed on agarose gel containing0.1% ethidium bromide and subcloned into a TA cloning vector(Invitrogen) for DNA sequencing.

In-situ hybridizations
Both [³⁵S]UTP-labelled sense and antisense probes were synthesizedby in-vitro transcription using human MATER cDNA as templatesand T₃/T₇ RNA polymerase (Ambion, Inc., Austin, TX, USA). Shortprobes (~300 nt) of alkaline hydrolysis were hybridized at 60°Cfor 24 h with frozen sections (8 µm) of human ovary obtainedfrom the National Disease Research Institute (NDRI; Philadelphia,PA, USA). After dipping in Kodak NTB-2 emulsion, the slideswere exposed for 1 week on an X-ray film for developing in KodakD-19 and Kodak Fixer. The slides were finally stained with haematoxylinand eosin, and examined by microscopy under both dark and lightfields.

Immunohistochemistry and immunoblotting
After blocking with 10% normal goat sera in phosphate-bufferedsaline (PBS), frozen sections (8 µm) of human ovary (NDRI)were incubated at 25°C for 2 h with rabbit antisera (1:200)specific to mouse MATER peptide. The slides were washed with0.05% Tween-20 in PBS, and incubated with a goat anti-rabbitIgG antibody conjugated with fluorescein isothiocyanate (1:300;Sigma Chemical Co., St Louis, MO, USA). After washing and applyingwith glycerol–glass cover, the slides were examined underfluorescent microscopy. Human immature oocytes were suppliedfor this study by a clinical IVF programme (Invitrogen; Origene)after obtaining consent and approval of the NIH Office of HumanSubjects Research. For immunoblotting, human oocyte proteinswere separated on 3–8% Tris–acetate SDS–polyacrylamidegel electrophoresis. After transferring onto a nitrocellulosemembrane, 5% dry milk in PBS was used to block non-specificbinding in the blot. Subsequently, the blot was incubated withrabbit anti-MATER peptide antibody (1:1000) for 2 h at 25°C.After the blot was washed, the primary antibody-bound proteinswere detected by a goat anti-rabbit IgG antibody (1:1000) labelledwith horse-radish peroxidase using an enhanced chemiluminescencesystem according to the manufacturer's instructions (Amersham/Pharmacia,Inc., Piscataway, NJ, USA).

DNA sequencing and computational analysis
DNA was sequenced with a dRhodamine terminator cycle sequencingkit (PE Applied Biosystems, Foster City, CA, USA) accordingto the manufacturer's instructions. Sequencing reactions wereconducted by PCR at 25 cycles of 95°C, 10 s; 50°C, 5s; and 60°C, 4 min. Electrophoresis with 5% Long Rangergels and sequence analysis were carried out on the ABI Prism377 DNA Sequencer. Computational analyses of DNA sequences anddeduced peptide sequences were conducted using software availableat the National Center for Biotechnology Information at NIH(http://www.ncbi.nlm.nih.gov), the EMBL-EBI (http://www.ensembl.org),the Sanger Center (http://www.sanger.ac.uk) and the ExPASy MolecularBiology Server of the Swiss Institute for Bioinformatics (http://www.expasy.ch).

Results

Top
Abstract
Introduction
Materials and methods
Results
Discussion
Acknowledgements
References

Oocyte-specific expression of human MATER transcripts and protein
Using human MATER cDNA as a probe, a Northern blot hybridizationrevealed the presence of a single ~4.2 kb MATER transcript inthe human ovarian total RNA (Figure 1A). The human MATER transcriptsappeared to be larger than the mouse MATER transcript (3.75kb). The relatively greater abundance of MATER mRNA detectedin the ovarian RNA from a 19 year old woman (lane 1), comparedwith the RNA from 26 year old woman (lane 2), may reflect therelatively greater number of oocytes present in ovaries fromyounger women (Adashi, 1999).

View larger version (61K):
[in this window]
[in a new window]

Figure 1. Human MATER mRNA and its oocyte-specific expression. (A) Northern hybridization: total human ovarian RNA were prepared from women at age 19 (lane 1) and 26 (lane 2) years. 10 µg of each RNA were separated by gel electrophoresis and transferred onto a nitrocellulose membrane. The blot was probed with ³²P-labelled human MATER cDNA. RNA molecular sizes (kb) are indicated on the left of the panel. (B and C) RT–PCR: using the Human Rapid-Scan Gene Expression Panel (Origene Inc.) and specific primers, cDNA at x100 concentration was used to amplify human ß-actin (B), while cDNA at x1000 concentration was used to amplify human MATER (C). The cDNA was synthesized from the RNA of the human brain (lane 1), heart (2), kidney (3), spleen (4), liver (5), colon (6), lung (7), small intestine (8), muscle (9), stomach (10), testis (11), placenta (12), salivary gland (13), thyroid (14), adrenal gland (15), pancreas (16), ovary (17), uterus (18), prostate (19), skin (20), blood leukocytes (21), bone marrow (22), fetal brain (23), fetal liver (24). Lanes 25 and26 serve as a positive control (human ovarian cDNA; Invitrogen) and a negative control (without cDNA) respectively. PCR products were separated by 2% agarose gel electrophoresis and visualized by 0.1% ethidium bromide. Amplification of the PCR products of humanß-actin (640 bp) and human MATER (280 bp) is indicated on the right. (D) Southern hybridization: a blot was prepared from the agarose gel separating the human MATER PCR product in (C), and probed with ³²P-labelled human MATER cDNA. Hybridization signals were detected by autoradiography. Arrow indicates the position of PCR product hybridization of human MATER (280 bp) on the right. (E and F) In-situ hybridization: ³⁵S-labelled antisense and sense probes were synthesized by in-vitro transcription using the human MATER cDNA as templates. The frozen human ovarian sections were hybridized with the antisense probe (E) and sense probe (F). Dark-field images are displayed, and location of the oocytes is indicated by an arrow. Scale bar = 100 µm.

To determine whether expression of human MATER transcripts isovarian-specific, we performed PCR reactions using cDNA thatwere derived from human RNA of 24 different tissues (Human Rapid-ScanGene Expression Panel). As a control, shown in Figure 1B

, thePCR products (640 bp) of human ß-actin were amplifiedin all cDNA derived from 24 tissues and human ovary (lanes 1–25)using the human ß-actin-specific primers (5'-GCATGGGTCAGAAGGAT-3'/3'-GTCCAGTAGTGGTAACC-5').In contrast, using human MATER-specific primers (5'-TGACTTCTGATTGCTGTGAGG-3'/3'-CTACTGGCCATGACCACCTT-5'),the PCR products (280 bp) were only generated in the cDNA synthesizedfrom the ovarian RNA (Figure 1C

, lanes 17 and 25). Ovarian-specificexpression of the human MATER transcripts was further evidencedby a Southern blot hybridization of the human MATER primer-amplifiedPCR reactions probed with radiolabelled MATER cDNA (Figure 1D

).Furthermore, in-situ hybridization of human ovarian sectionsrevealed the oocyte-specific expression of human MATER transcripts.As shown in Figure 1E

, the hybridization signals using synthetichuman MATER antisense probe were present within the oocytesbut not in the follicular cells. The control MATER sense probesdid not hybridize with oocytes or other ovarian cells (Figure1F

). Thus, this oocyte-restricted expression of the human MATERgene appeared similar to the expression pattern of mouse Matergene (Tong and Nelson, 1999

Expression of human MATER protein in oocytes was demonstratedby indirect immunofluorescence. Using a primary antibody ofrabbit anti-mouse MATER peptide, the oocytes present in thehuman ovarian sections were visualized by FITC-conjugated secondantibody (Figure 2A). No fluorescense was observed in the othersomatic cells within ovarian sections. Normal rabbit sera didnot stain the oocytes (data not shown). To determine the sizeof native MATER protein, human immature oocytes were used forimmunoblotting. As shown in Figure 2C, human MATER protein (~134kDa) was detected in the preparation of the human oocyte proteinsusing anti-mouse MATER antibody. It was noted that there weretwo close signals of MATER proteins present in the immunoblotting.This might reflect a post-translational modification of humanMATER protein or a possibility of an alternative initiationsite in the synthesis of the polypeptide chain.

View larger version (70K):
[in this window]
[in a new window]

Figure 2. Human MATER protein expression in the oocytes. (A and B) Immunohistofluorescence: frozen human ovarian sections were incubated with rabbit antisera (1:200) against the mouse MATER peptide. Fluorescein isothiocyanate-conjugated goat anti-rabbit IgG antibody was used as a second antibody to detect the primary antibody bound MATER protein. Tissue sections were visualized by fluorescence microscopy (A). Corresponding phase contrast is shown in (B). Arrows indicate the location of oocytes. Scale bar = 100 µm. (C) Immunoblotting: solubilized proteins of human oocytes (lane 1, 10 oocytes; lane 2, 15 oocytes) were separated by 3–8% Tris–acetate SDS–PAGE electrophoresis. A protein blot was incubated with rabbit anti-mouse MATER peptide antisera (1:1000). The enhanced chemiluminescence kit with horse-radish peroxidase-conjugated goat anti-rabbit IgG antibody was used to detect the blot-bound primary antibodies. Protein molecular masses (kDa) are indicated on the left. Human MATER protein is indicated by an arrow at ~134 kDa.

Isolation and characterization of human MATER cDNA
The mouse MATER cDNA sequence was blasted to the htgs databaseto search for human DNA sequences homologous to the mouse MATERcDNA. A serial of discontinuous and short DNA sequences homologouswith the mouse MATER cDNA was initially found in the genomicclones (AC012107, AC024580, AC019238 and AC023887) of humanchromosome 19. This finding held promise for locating the humanMATER, since the human chromosome 19q13 is a syntenic regionof the mouse Mater residing at the proximal end of the mousechromosome 7 (Tong et al., 2000b

). We designed human oligonucleotideprimers and amplified the PCR products from human ovarian cDNAand its library. Using these PCR-cloned cDNA as the probes forin-situ hybridization, the human oocytes were confirmed to expressthe corresponding transcripts. DNA sequencing revealed thatthese PCR products are human MATER cDNA homologous to the mouseMATER cDNA.

The PCR products were generated to span ~98% of the coding regionfrom nt 76 to nt 3596. The 3' non-coding regions were determinedby sequencing cDNA clones isolated from the human ovarian cDNAlibrary using the PCR-cloned cDNA as probe. The first 75 ntat the 5' end were derived from a predicted cDNA of the genomicclone AC011470 (http://www.ensembl.org). The non-coding regionpresent at the 5' end of the MATER cDNA remains undetermined.Assuming the presence of a poly(A) tail (~150–200 nt)and the 5' undetermined non-coding regions (~100–150 nt),assembly of our determined human MATER cDNA sequence, its poly(A)tail and 5' undetermined non-coding region corresponded in sizewith the MATER transcripts detected in the Northern hybridization(4.2 kb). This suggests that the cloned cDNA represents a fulllength of the coding region. As shown in Figure 3, the openreading frame (nt 1 to nt 3600) of the cloned cDNA (3885 nt)encodes a protein composed of 1200 amino acids (Figure 3). Theentire polypeptide chain was predicted to have a pI 6.08 anda molecular mass of 134 235.76 Da, which corresponded to thesize of the human oocyte protein recognized by the antiseraspecific to mouse MATER peptide. Expression of a recombinantprotein further confirmed the cloned cDNA to encode the humanMATER protein (data not shown).

View larger version (87K):
[in this window]
[in a new window]

Figure 3. Nucleotide and amino acid sequences of human MATER. The nucleotides (3885 nt) from 5' are displayed on the top line and their numbers are indicated on the right. The initiation code (ATG) and termination code (TGA) is underlined (solid) respectively. The polyadenylation signal (AATAAA) is underlined with a dashed line. The nucleotides at the 5' end of the non-coding region remain to be determined. The deduced amino acid sequence (1200 residues) is under the nucleotide sequence and numbered on the right. Some structural motifs present in the protein sequence are shown in Figure 5B

. These sequence data are submitted to the GenBank under an accession number AY054986.

The initiator code (ATG) encoding the first methionine in theopen reading frame (ORF) was in a context (ATC-ATGAAG), theconsensus sequence recognized for initiation in vertebrates(Kozak, 1991

). The stop code (TGA) was followed by 282 nt ofthe 3' non-coding sequence. A signal sequence (AATAAA) for polyadenylationwas located just 18 nt upstream of the poly(A) tail. None ofthe known genes and proteins deposited in the GenBank was foundto have significant homologies to the human MATER gene or MATERprotein. However, the carboxyl-terminal sequence of the humanMATER peptide had an ~32% homology with human and porcine ribonucleaseinhibitors (457 residues). Thus, human MATER contains a structuraldomain of the ribonuclease inhibitor-like leucine-rich repeatsat the carboxyl-terminus (see below), as found in mouse MATER(Kajava 1998

; Tong et al., 2000b

). The human and mouse MATERcDNA shared 67% homology while their deduced polypeptide chainshad 53% identities of amino acids.

Analysis of human MATER polypeptide chain
A computational analysis was carried out to search for the structuralfeatures of human MATER protein. When the entire polypeptidechain of human MATER was compared with itself, the Dotplot analysisrevealed the presence of repeat structural motifs at amino-and carboxyl-termini. These repeats were evidenced by a seriesof parallel but offset lines in these regions (Figure 4A), asalso seen in the mouse MATER protein (Tong et al., 2000b). Acomparison between the polypeptide chains of human and mouseMATER indicated the similarities and homologies of their structuralmotifs and compositions (Figure 4B).

View larger version (24K):
[in this window]
[in a new window]

Figure 4. Dotplot analysis of human and mouse MATER amino acid sequences. Human MATER amino acid sequence was compared with itself (A) and the mouse MATER amino acid sequence (B). The centre diagonal line from the left to the right represents the direct correspondence of the two sequences of the same protein from amino- to carboxyl-terminus. Identities are shown by the dots. The short diagonal lines parallel to the centre diagonal line are present at the carboxyl-terminus and a region close to the amino-terminus, reflecting repeated amino acid sequences at these regions. Display of the dots and short parallel lines delineate similarities of amino acid sequences between human MATER (1200 residues) and mouse MATER (1111 residues), reflecting homologies of the composition and structure of the MATER protein of the two species.

A hydropathy plot (Figure 5A

) indicated that there were hydrophilicregions present at amino-(32–304 residues) and carboxyl-termini(1184–1200 residues) (Kyte and Doolittle, 1982

). No structuralmotifs were found for either peptide signals of protein secretionor transmembrane domains. The peptide chain had some notablemotifs as indicated in Figure 5B

. A signal for nuclear localizationwas present at the residue 517–534 (NLS_BP), which wasnot detected in the mouse MATER. Because of the absence of thepeptide domains for DNA binding, further experimental evidenceis required to determine if the human MATER is translocatedinto nuclei. Human MATER protein had six leucine-rich repeatsat the carboxyl-terminus and a PAAD_DAPIN domain (52–148residues), both of which are recognized as the structural basisfor protein–protein interactions (Kobe and Deisenhofer,1995

; Pawlowski et al., 2001

; Staub et al., 2001

). Their presenceimplies that human MATER probably interacts with other oocyteproteins to perform its function. In addition, human MATER proteinhad an aldo_ket_red domain (71–87) at the amino-terminusand an ATP-/GTP-binding domain (P-loop) at residue 286–293.The aldo_ket_red is a domain present in protein with oxidoreductaseactivity (Bohren et al., 1989

), and the P-loop is the typicaldomain for binding to ATP/GTP in participating in an intracellularsignal transduction (Saraste et al., 1990

). The roles of thesedomains in the function of human MATER protein remain to bedetermined.

View larger version (47K):
[in this window]
[in a new window]

Figure 5. Computational analysis of structural motifs in human MATER. (A) Kyte and Doolittle hydropathy of human MATER amino acid sequence. Hydrophilic repeats at the amino-terminus (32–304 amino acids) contain a short hydrophobic region (104–136 amino acids). At the carboxyl-terminus, there is a short hydrophilic region (1184–1200 amino acids). (B) Schematic representation of structural motifs of human MATER. The horizontal line from amino- to carboxyl-terminus represents the entire peptide chain of human MATER (1200 residues). The opened boxes represent structural motifs and their positions on the peptide chain. The protein contains a domain of PAAD_DAPIN at the amino-terminus and six domains of leucine-rich repeats (LRR) at the carboxyl-terminus. Both molecular domains are for protein–protein interactions. In addition, there are motifs with potentials forATP/GTP-binding (P-loop), nuclear translocation (NLS_BP) and aldo/keto reductase activity (aldo_ket_red). Locations of these motifs are indicated in the numbers following the particular motifs.

Genomic organization of human MATER locus
Using the sequence of the cloned human MATER cDNA to blast thehuman hgts database (http://www.ensembl.org), a single genomicclone (AC011740) with a full DNA sequence was determined toharbour an entire gene locus of human MATER. To determine thenumber and size of the exons and introns, the sequence of thecloned cDNA was compared with the sequence of the AC011740 cloneisolated from human chromosome 19. The 15 exons and 14 intronswere identified to span a ~63 kbp DNA. The exons ranging insize from 56 to 1597 bp were intervened by the 14 introns rangingfrom 760 to 9327 bp (Table I

). In addition, there were 282 nucleotidesof the 3' non-coding region within exon 15, and undeterminednucleotides of the 5' non-coding region within exon 1. The sequencesswitching between each exon and intron were confirmed to meetwith the bordering consensus sequences (AG ${approx}$ GT) for splice sitesof the exon–intron (Breathnach and Chambon, 1981

). Thus,human MATER locus spanned a ~63 kbp DNA and was composed ofthe 15 exons and 14 introns.

View this table:
[in this window]
[in a new window]

Table I. Exon and intron and splice-junction sequences of human MATER

Human MATER and mouse Mater loci had identical numbers of exonsand introns, while the human locus was longer than the mouselocus (32 kbp). This mainly reflects the larger size of thehuman introns. The counterpart exons were comparable. Both hada large exon 7 spanning ~50% of the coding sequences, and thecounterparts of exons 8–14 had an identical number ofnucleotides. However, the first six exons (1–6) in thehuman locus ranged in size from 56 to 380 nt while their counterpartsin the mouse locus had 48–78 nt. A larger exon 2 (380nt) in the human MATER locus made the human MATER cDNA codingregion (3600 nt) slightly longer than the mouse cDNA codingregion (3333 nt). All of these structural similarities and variationsreflect a genetic conservation and evolution between mouse Materand human MATER loci.

Discussion

Top
Abstract
Introduction
Materials and methods
Results
Discussion
Acknowledgements
References

Human MATER and mouse Mater genes and proteins are conserved.Their cDNA share 67% homology in the nucleotide sequence andtheir deduced polypeptide chains have 53% identities of aminoacids. The human and mouse MATER proteins share a number ofsimilar features, such as leucine-rich repeat at the carboxyl-terminusand an ATP-/GTP-binding domain (P-loop). These structural similaritiesbetween species suggest that MATER may have a similar functionin the mouse and human. In mice, we have demonstrated that MATERplays a critical role in early development and that its absencecauses female infertility (Tong et al., 2000a), and also thatMATER serves as an oocyte-specific autoantigen associated withovarian autoimmunity (Tong and Nelson, 1999). Thus, MATER mayhave potential clinical implications in autoimmune prematureovarian failure and infertility in women. Characterization ofhuman MATER and its protein provides a basis for investigatingthese women's diseases.

The requirement of MATER for early embryonic development inmice is an example of how important the role of maternal productscan be in the developmental programme of mammals (Tong et al.,2000a). The role of MATER appears to be specific to very earlydevelopment. In mice, Mater null mutation does not affect oogenesis,folliculogenesis, oocyte maturation and ovulation, or fertilization.Phenotypic infertility in the null female mice lacking MATERis attributable to an arrested development at the 2-cell stage.The arrested embryos demonstrate a considerable decrease ofembryonic gene transcription. The resultant 2-cell block appearssimilar to observations of mouse embryos treated with ${alpha}$ -amanitin,in which the metabolic blockage of embryonic transcription resultsin an arrest of embryonic development specific to the 2-cellstage (Warner and Versteegh, 1974; Flach et al., 1982). MATERconsistently remains within the embryonic cytoplasm during mousedevelopment to the blastcyst stage. The exact function of MATERremains to be determined. The presence of an ATP-/GTP-bindingdomain in both human and mouse MATER proteins suggests theirparticipation in an intracellular signal transduction (Sarasteet al., 1990). Our preliminary data indicate that MATER maybe truly involved in cellular signaling (Z.-B.Tong et al., unpublishedobservations). In addition to the carboxyl-terminal leucine-richrepeat domain similar to the mouse MATER (Tong et al., 2000b),human MATER has an amino-terminal PAAD_DAPIN domain (Pawlowskiet al., 2001; Staub et al., 2001). Both domains are recognizedas structural motifs for mediating protein–protein interactions(Kobe and Deisenhofer 1995; Pawlowski et al., 2001), raisinga possibility that MATER may interact with other protein(s)within the embryos. Different from the mouse MATER, human MATERprotein has an amino-terminal aldo_ket_red domain, a motif ofproteins with oxidoreductase activity (Bohren et al., 1989),and a signal for nuclear localization. Further experiments arerequired to determine the significance of these structural motifs.

Although little is known about maternal embryonic effect inhumans, increasing evidence indicates that maternal factorspresent in human oocytes perform a critical role in biologicalevents following fertilization (Barritt et al., 2001). Amonginfertile women seeking reproductive assistance in clinicalIVF programmes, not all women reach a desirable outcome sincethe in-vitro fertilized oocytes of some women fail to undergonormal early embryonic development (Alikani et al., 1999; Kovacset al., 2001). It is a possibility that the maternal factor(s)necessary for supporting early development is defective in thefertilized ova of some infertile women. Indeed, recent reportssuggest that injection of normal oocyte proteins into the oocytesof some infertile women might restore normal early developmentand successful pregnancy (Cohen et al., 1997; Barritt et al.,2001). However, specific factors rescuing early developmenthave not been identified. Mater null female mice are infertilebecause the absence of MATER protein in the fertilized ova leadsto failure in embryonic development. We propose that a homozygoushuman MATER mutation or its protein deficiency may cause infertilityin some women. To test this hypothesis, we plan to examine infertilewomen with a history of successful fertilization but yet failurein embryonic development for gene mutations of human MATER.If such a deficiency is found, normal embryonic developmentmight be induced by injection of recombinant human MATER proteininto the oocytes before fertilization. This might provide IVFprogrammes with a novel therapy to treat infertile women whohave a homozygous MATER mutation and the resulting oocyte proteindeficiency.

Cloning and characterization of human MATER might also leadto insights regarding the pathogenesis of human autoimmune prematureovarian failure. This ovarian disease is a clinical syndromecharacterized by amenorrhoea, infertility and menopausal symptomsattributable to hypoestrogenaemia and hypergonadotrophinaemiain women before age 40 (Kalantaridou and Nelson, 2000). However,specific ovarian antigenic targets involved in autoimmune prematureovarian failure have yet to be identified (Hoek et al., 1997).There are striking similarities between human autoimmune prematureovarian failure and the autoimmune oophoritis in an animal model,which is generated by neonatal thymectomy in certain strainsof mice (Taguchi et al., 1980; Taguchi and Nishizuka, 1980;Kalantaridou and Nelson, 2000). MATER was first identified asan oocyte-specific antigen associated with autoimmune oophoritisin this thymectomy mouse model (Tong and Nelson, 1999). A recentreport has shown that the endogenous oocyte antigen may be essentialfor development of auotimmune ovarian disease in this animalmodel (Alard et al., 2001). We are developing an assay usinghuman recombinant MATER protein to determine whether patientswith premature ovarian failure have circulating anti-MATER antibodies.If the outcome is positive, such an assay would help physiciansclassify patients with premature ovarian failure, and thus providea basis for developing therapy for the disease.

View larger version (13K):
[in this window]
[in a new window]

Figure 6. Schematic representations of exon–intron maps of human MATER (A) and mouse Mater (B). The exon–intron map of human MATER (~63 kbp) was compared with the mouse Mater (~32 kbp) exon–intron map (Tong et al., 2000b). Both gene loci have 15 exons that are indicated by the Arabic numbers above each of the vertical bars representing the exons. The horizontal solid lines between exons represent introns, and the horizontal dashed lines at 5' ends represent the undetermined 5' ends of both gene loci. Scale bar (2 kbp) is shown under the map of human MATER.

	Acknowledgements

Top Abstract Introduction Materials and methods Results Discussion Acknowledgements References

We thank Dr David Wheeler for initial instruction of the humanhtgs database, Dr Jurrien Dean and Dr Jeffrey Trent for earlydiscussions and Dr Jie Wang for technical assistance with in-situhybridization. We are grateful to Dr Roger Gosden for providinghuman ovarian RNA and Dr Robert Stillman for assistance in obtainingimmature human oocytes. The NIH has filed a patent applicationconcerning the subject of this manuscript.

Notes

¹ To whom correspondence should be addressed at: Building 10,Room 10N262, Developmental Endocrinology Branch, NICHD, NIH,10 Center Drive, Bethesda, MD 20892-1862, USA. E-mail: tongz{at}cc1.nichd.nih.gov

References

Top
Abstract
Introduction
Materials and methods
Results
Discussion
Acknowledgements
References

Adashi, E.Y. (1999) The ovarian life cycle. In Yen, S.S.C. et al. (eds), Reproductive Endocrinology, 4th edn, W.B.Saunders, Philadelphia, pp. 153–190.

Akam, M. (1987) The molecular basis for metameric pattern in the Drosophila embryo. Development, 101, 1–22.[Abstract]

Alard, P., Thompson, C., Agersborg, S.S., Thatte, J., Setiady, Y., Samy, E. and Tung, K.S. (2001) Endogenous oocyte antigens are required for rapid induction and progression of autoimmune ovarian disease following day-3 thymectomy. J. Immunol., 166, 4363–4369.[Abstract/Free Full Text]

Alikani, M., Cohen, J., Tomkin, G., Garrisi, G.J., Mack, C. and Scott, R.T. (1999) Human embryo fragmentation in vitro and its implications for pregnancy and implantation. Fertil. Steril., 71, 836–842.[Web of Science][Medline]

Aoki, F., Worrad, D.M. and Schultz, R.M. (1997) Regulation of transcriptional activity during the first and second cell cycles in the preimplantation mouse embryo. Dev. Biol., 181, 296–307.[Web of Science][Medline]

Barritt, J., Willadsen, S., Brenner, C. and Cohen, J. (2001) Cytoplasmic transfer in assisted reproduction. Hum. Reprod. Update, 7, 428–435.[Abstract/Free Full Text]

Bellier, S., Chastant, S., Adenot, P., Vincent, M., Renard, J.P. and Bensaude, Q. (1997) Nuclear translocation and carboxyl-terminal domain phosphorylation of RNA polymerase delineate the two phases of zygotic gene activation in mammalian embryos. EMBO J., 16, 6250–6262.[Web of Science][Medline]

Bohren, K.M., Bullock, B., Wermuth, B. and Gabbay, K.H. (1989) The aldo-keto reductase superfamily. cDNAs and deduced amino acid sequences of human aldehyde and aldose reductases. J. Biol. Chem., 264, 9547–9551.[Abstract/Free Full Text]

Bouniol, C., Nguyen, E. and Debey, P. (1995) Endogenous transcription occurs at the 1-cell stage in the mouse embryo. Exp. Cell Res., 218, 57–62.[Web of Science][Medline]

Breathnach, R. and Chambon, P. (1981) Organization and expression of eucaryotic split genes coding for proteins. Annu. Rev. Biochem., 50, 349–383.[Web of Science][Medline]

Christians, E., Davis, A.A., Thomas, S.D. and Benjamin, I.J. (2000) Maternal effect of Hsf1 on reproductive success. Nature, 407, 693–694.[Medline]

Cohen, J., Scott, R., Schimmel, T., Levron, J. and Willadsen, S. (1997) Birth of infant after transfer of anucleate donor oocyte cytoplasm into recipient eggs. Lancet, 350, 186–187.[Web of Science][Medline]

Conover, J.C., Temeles, G.L., Zimmermann, J.W., Burke, B. and Schultz, R.M. (1991) Stage-specific expression of a family of proteins that are major products of zygotic gene activation in the mouse embryo. Dev. Biol., 144, 392–404.[Web of Science][Medline]

Droin, A. (1992) The developmental mutants of Xenopus. Int. J. Dev. Biol., 36, 455–464.[Web of Science][Medline]

Flach, G., Johnson, M.H., Braude, P.R., Taylor, R.A. and Bolton, V.N. (1982) The transition from maternal to embryonic control in the 2-cell mouse embryo. EMBO J., 1, 681–686.[Web of Science][Medline]

Hoek, A., Schoemaker, J. and Drexhage, H.A. (1997) Premature ovarian failure and ovarian autoimmunity. Endocr. Rev., 18, 107–134.[Abstract/Free Full Text]

Kalantaridou, S.N. and Nelson, L.M. (1998) Autoimmune premature ovarian failure: of mice and women. J. Am. Women Assoc., 53, 10–20.

Kalantaridou, S.N. and Nelson, L.M. (2000) Premature ovarian failure is not premature menopause. Ann. NY Acad. Sci., 900, 393–402.[Web of Science][Medline]

Kajava, A.V. (1998) Structural diversity of leucine-rich repeat proteins. J. Mol. Biol., 277, 519–527.[Web of Science][Medline]

Kobe, B. and Deisenhofer, J. (1995) Proteins with leucine-rich repeats. Curr. Opin. Struct. Biol., 5, 409–416.[Web of Science][Medline]

Kovacs, G.T., Maclachlan, V. and Brehny, S. (2001) What is the probability of conception for couple entering an IVF program? Aust. NZ J. Obstet. Gynaecol., 41, 207–209.[Web of Science][Medline]

Kozak, M. (1991) Structural features in eukaryotic mRNAs that modulate the initiation of translation. J. Biol. Chem., 266, 19876–19870.

Kyte, J. and Doolittle, R.F. (1982) A simple method for displaying the hydropathic character of a protein. J. Mol. Biol., 157, 105–132.[Web of Science][Medline]

Larue, L., Ohsugi, M., Hirchenhain, J. and Kemler, R. (1994) E-cadherin null mutant embryos fail to form a trophectoderm epithelium. Proc. Natl Acad. Sci. USA, 91, 8263–8267.[Abstract/Free Full Text]

Latham, K.E. (1999) Mechanisms and control of embryonic genome activation in mammalian embryos. Int. Rev. Cytol., 193, 71–124.[Web of Science][Medline]

Latham, K.E. and Schultz, R.M. (2001) Embryonic genome activation. Front. Biosci., 6, D748–759.[Web of Science][Medline]

Latham, K.E., Garrels, J.I., Chang, C. and Solter, D. (1991a) Quantitative analysis of protein synthesis in mouse embryos. I. Extensive reprogramming at the one- and two-cell stages. Development, 112, 921–932.[Abstract]

Latham, K.E., Solter, D. and Schultz, R.M. (1991b) Activation of a two-cell stage-specific gene following transfer of heterologous nuclei into enucleated mouse embryos. Mol. Reprod. Dev., 30, 182–186.[Web of Science][Medline]

Nothias, J.Y., Majumder, S., Kaneko, K.J. and DePamphilis, M.L. (1995) Regulation of gene expression at the beginning of mammalian development. J. Biol. Chem., 270, 22077–22080.[Free Full Text]

Pawlowski, K., Pio, F., Chu, Z., Reed, J.C. and Godzik, A. (2001) PAAD—a new protein domain associated with apoptosis, cancer and autoimmune diseases. Trends Biochem. Sci., 26, 85–87.[Web of Science][Medline]

Rankin, T.L., Soyal, S. and Dean, J. (2000) The mouse zona pellucida: folliculogenesis, fertility and pre-implantation development. Mol. Cell. Endocrinol., 163, 21–25.[Web of Science][Medline]

Rankin, T.L., O'Brien, M., Lee, E., Wigglesworth, K., Eppig, J. and Dean, J. (2001) Defective zonae pellucidae in Zp2-null mice disrupt folliculogenesis, fertility and development. Development, 128, 1119–1126.[Abstract]

Saraste, M., Sibbald, P.R. and Wittinghofer, A. (1990) The P-loop—a common motif in ATP- and GTP-binding proteins. Trends Biochem. Sci., 15, 430–434.[Web of Science][Medline]

Schultz, R.M. (1993) Regulation of zygotic gene activation in the mouse. Bioessay, 8, 531–538.

Staub, E., Dahl, E. and Rosenthal, A. (2001) The DAPIN family: a novel domain links apoptotic and interferon response proteins. Trends Biochem. Sci., 26, 83–85.[Web of Science][Medline]

Taguchi, O. and Nishizuka, Y. (1980) Autoimmune oophoritis in the thymectomized mice: T cell requirement in adoptive cell transfer. Clin. Exp. Immunol., 42, 324–331.[Web of Science][Medline]

Taguchi, O., Nishizuka, Y., Sakakura, T. et al. (1980) Autoimmune oophoritis in thymectomized mice: detection of circulating antibodies against oocytes. Clin. Exp. Immunol., 40, 540–553.[Web of Science][Medline]

Tong, Z.B. and Nelson, L.M. (1999) A mouse gene encoding an oocyte antigen associated with autoimmune premature ovarian failure. Endocrinology, 140, 3720–3726.[Abstract/Free Full Text]

Tong, Z.B., Gold, L., Pfeifer, K.E., Dorward, H., Lee, E., Bondy, C.A., Dean, J. and Nelson, L.M. (2000a) Mater, a maternal effect gene required for early development in mice. Nat. Genet., 26, 267–268.[Web of Science][Medline]

Tong, Z.B., Nelson, L.M. and Dean, J. (2000b) Mater encodes a maternal protein in mice with a leucine-rich repeat domain homologous to porcine ribonuclease inhibitor. Mamm. Genome, 11, 281–287.[Web of Science][Medline]

Warner, C.M. and Versteegh, L.R. (1974) In vivo and in vitro effect of ${alpha}$ -amanitin on preimplantation mouse embryo RNA polymerase. Nature, 248, 678–680.[Medline]

Submitted on September 26, 2001; accepted on November 27, 2001.

Add to CiteULike CiteULike Add to Connotea Connotea Add to Del.icio.us Del.icio.us What's this?

This article has been cited by other articles:

T. Maraldi, M. Riccio, P. Sena, L. Marzona, A. Nicoli, A. La Marca, S. Marmiroli, J. Bertacchini, G. La Sala, and A. De Pol
MATER protein as substrate of PKC{varepsilon} in human cumulus cells
Mol. Hum. Reprod., August 1, 2009; 15(8): 499 - 506.
[Abstract] [Full Text] [PDF]

C M Wang, P H Dixon, S Decordova, M D Hodges, N J Sebire, S Ozalp, M Fallahian, A Sensi, F Ashrafi, V Repiska, et al.
Identification of 13 novel NLRP7 mutations in 20 families with recurrent hydatidiform mole; missense mutations cluster in the leucine-rich region
J. Med. Genet., August 1, 2009; 46(8): 569 - 575.
[Abstract] [Full Text] [PDF]

P. A. Fowler, S. Flannigan, A. Mathers, K. Gillanders, R. G. Lea, M. J. Wood, A. Maheshwari, S. Bhattacharya, E. S. R. Collie-Duguid, P. J. Baker, et al.
Gene Expression Analysis of Human Fetal Ovarian Primordial Follicle Formation
J. Clin. Endocrinol. Metab., April 1, 2009; 94(4): 1427 - 1435.
[Abstract] [Full Text] [PDF]

X. Wu
Maternal depletion of NLRP5 blocks early embryogenesis in rhesus macaque monkeys (Macaca mulatta)
Hum. Reprod., February 1, 2009; 24(2): 415 - 424.
[Abstract] [Full Text] [PDF]

J. M. Wilmanski, T. Petnicki-Ocwieja, and K. S. Kobayashi
NLR proteins: integral members of innate immunity and mediators of inflammatory diseases
J. Leukoc. Biol., January 1, 2008; 83(1): 13 - 30.
[Abstract] [Full Text] [PDF]

F. Bedoya, L. L. Sandler, and J. A. Harton
Pyrin-Only Protein 2 Modulates NF-{kappa}B and Disrupts ASC:CLR Interactions
J. Immunol., March 15, 2007; 178(6): 3837 - 3845.
[Abstract] [Full Text] [PDF]

S. Ponsuksili, R. M. Brunner, T. Goldammer, C. Kuhn, C. Walz, S. Chomdej, D. Tesfaye, K. Schellander, K. Wimmers, and M. Schwerin
Bovine NALP5, NALP8, and NALP9 Genes: Assignment to a QTL Region and the Expression in Adult Tissues, Oocytes, and Preimplantation Embryos
Biol Reprod, March 1, 2006; 74(3): 577 - 584.
[Abstract] [Full Text] [PDF]

S. Pennetier, S. Uzbekova, C. Guyader-Joly, P. Humblot, P. Mermillod, and R. Dalbies-Tran
Genes Preferentially Expressed in Bovine Oocytes Revealed by Subtractive and Suppressive Hybridization
Biol Reprod, October 1, 2005; 73(4): 713 - 720.
[Abstract] [Full Text] [PDF]

P. C. Panichkul, T. K. Al-Hussaini, R. Sierra, C. D. Kashork, E. J. Popek, D. W. Stockton, and I. B. Van den Veyver
Recurrent Biparental Hydatidiform Mole: Additional Evidence for a 1.1-Mb Locus in 19q13.4 and Candidate Gene Analysis
Reproductive Sciences, July 1, 2005; 12(5): 376 - 383.
[Abstract] [PDF]

T. Hamatani, G. Falco, M. G. Carter, H. Akutsu, C. A. Stagg, A. A. Sharov, D. B. Dudekula, V. VanBuren, and M. S.H. Ko
Age-associated alteration of gene expression patterns in mouse oocytes
Hum. Mol. Genet., October 1, 2004; 13(19): 2263 - 2278.
[Abstract] [Full Text] [PDF]

S. Pennetier, S. Uzbekova, C. Perreau, P. Papillier, P. Mermillod, and R. Dalbies-Tran
Spatio-Temporal Expression of the Germ Cell Marker Genes MATER, ZAR1, GDF9, BMP15,andVASA in Adult Bovine Tissues, Oocytes, and Preimplantation Embryos
Biol Reprod, October 1, 2004; 71(4): 1359 - 1366.
[Abstract] [Full Text] [PDF]

A. T. Dobson, R. Raja, M. J. Abeyta, T. Taylor, S. Shen, C. Haqq, and R. A. R. Pera
The unique transcriptome through day 3 of human preimplantation development
Hum. Mol. Genet., July 15, 2004; 13(14): 1461 - 1470.
[Abstract] [Full Text] [PDF]

T. Forges, P. Monnier-Barbarino, G.C. Faure, and M.C. Bene
Autoimmunity and antigenic targets in ovarian pathology
Hum. Reprod. Update, March 1, 2004; 10(2): 163 - 175.
[Abstract] [Full Text] [PDF]

M D Hodges, H C Rees, M J Seckl, E S Newlands, and R A Fisher
Genetic refinement and physical mapping of a biparental complete hydatidiform mole locus on chromosome 19q13.4.
J. Med. Genet., August 1, 2003; 40(8): e95 - 95.
[Full Text] [PDF]

L. Wang, G. A. Manji, J. M. Grenier, A. Al-Garawi, S. Merriam, J. M. Lora, B. J. Geddes, M. Briskin, P. S. DiStefano, and J. Bertin
PYPAF7, a Novel PYRIN-containing Apaf1-like Protein That Regulates Activation of NF-kappa B and Caspase-1-dependent Cytokine Processing
J. Biol. Chem., August 9, 2002; 277(33): 29874 - 29880.
[Abstract] [Full Text] [PDF]

This Article

Abstract

FREE Full Text (PDF )

Submit a response

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Services

Email this article to a friend

Similar articles in this journal

Similar articles in ISI Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Add to My Personal Archive

Download to citation manager

Search for citing articles in:
ISI Web of Science (37)

Request Permissions

Google Scholar

Articles by Tong, Z.-B.

Articles by Nelson, L. M.

Search for Related Content

PubMed

PubMed Citation

Articles by Tong, Z.-B.

Articles by Nelson, L. M.

Social Bookmarking

What's this?

				C M Wang, P H Dixon, S Decordova, M D Hodges, N J Sebire, S Ozalp, M Fallahian, A Sensi, F Ashrafi, V Repiska, et al. Identification of 13 novel NLRP7 mutations in 20 families with recurrent hydatidiform mole; missense mutations cluster in the leucine-rich region J. Med. Genet., August 1, 2009; 46(8): 569 - 575. [Abstract] [Full Text] [PDF]

				P. A. Fowler, S. Flannigan, A. Mathers, K. Gillanders, R. G. Lea, M. J. Wood, A. Maheshwari, S. Bhattacharya, E. S. R. Collie-Duguid, P. J. Baker, et al. Gene Expression Analysis of Human Fetal Ovarian Primordial Follicle Formation J. Clin. Endocrinol. Metab., April 1, 2009; 94(4): 1427 - 1435. [Abstract] [Full Text] [PDF]

				X. Wu Maternal depletion of NLRP5 blocks early embryogenesis in rhesus macaque monkeys (Macaca mulatta) Hum. Reprod., February 1, 2009; 24(2): 415 - 424. [Abstract] [Full Text] [PDF]

				J. M. Wilmanski, T. Petnicki-Ocwieja, and K. S. Kobayashi NLR proteins: integral members of innate immunity and mediators of inflammatory diseases J. Leukoc. Biol., January 1, 2008; 83(1): 13 - 30. [Abstract] [Full Text] [PDF]

				F. Bedoya, L. L. Sandler, and J. A. Harton Pyrin-Only Protein 2 Modulates NF-{kappa}B and Disrupts ASC:CLR Interactions J. Immunol., March 15, 2007; 178(6): 3837 - 3845. [Abstract] [Full Text] [PDF]

				S. Ponsuksili, R. M. Brunner, T. Goldammer, C. Kuhn, C. Walz, S. Chomdej, D. Tesfaye, K. Schellander, K. Wimmers, and M. Schwerin Bovine NALP5, NALP8, and NALP9 Genes: Assignment to a QTL Region and the Expression in Adult Tissues, Oocytes, and Preimplantation Embryos Biol Reprod, March 1, 2006; 74(3): 577 - 584. [Abstract] [Full Text] [PDF]

				S. Pennetier, S. Uzbekova, C. Guyader-Joly, P. Humblot, P. Mermillod, and R. Dalbies-Tran Genes Preferentially Expressed in Bovine Oocytes Revealed by Subtractive and Suppressive Hybridization Biol Reprod, October 1, 2005; 73(4): 713 - 720. [Abstract] [Full Text] [PDF]

				P. C. Panichkul, T. K. Al-Hussaini, R. Sierra, C. D. Kashork, E. J. Popek, D. W. Stockton, and I. B. Van den Veyver Recurrent Biparental Hydatidiform Mole: Additional Evidence for a 1.1-Mb Locus in 19q13.4 and Candidate Gene Analysis Reproductive Sciences, July 1, 2005; 12(5): 376 - 383. [Abstract] [PDF]

				T. Hamatani, G. Falco, M. G. Carter, H. Akutsu, C. A. Stagg, A. A. Sharov, D. B. Dudekula, V. VanBuren, and M. S.H. Ko Age-associated alteration of gene expression patterns in mouse oocytes Hum. Mol. Genet., October 1, 2004; 13(19): 2263 - 2278. [Abstract] [Full Text] [PDF]

				S. Pennetier, S. Uzbekova, C. Perreau, P. Papillier, P. Mermillod, and R. Dalbies-Tran Spatio-Temporal Expression of the Germ Cell Marker Genes MATER, ZAR1, GDF9, BMP15,andVASA in Adult Bovine Tissues, Oocytes, and Preimplantation Embryos Biol Reprod, October 1, 2004; 71(4): 1359 - 1366. [Abstract] [Full Text] [PDF]

				A. T. Dobson, R. Raja, M. J. Abeyta, T. Taylor, S. Shen, C. Haqq, and R. A. R. Pera The unique transcriptome through day 3 of human preimplantation development Hum. Mol. Genet., July 15, 2004; 13(14): 1461 - 1470. [Abstract] [Full Text] [PDF]

				T. Forges, P. Monnier-Barbarino, G.C. Faure, and M.C. Bene Autoimmunity and antigenic targets in ovarian pathology Hum. Reprod. Update, March 1, 2004; 10(2): 163 - 175. [Abstract] [Full Text] [PDF]

				M D Hodges, H C Rees, M J Seckl, E S Newlands, and R A Fisher Genetic refinement and physical mapping of a biparental complete hydatidiform mole locus on chromosome 19q13.4. J. Med. Genet., August 1, 2003; 40(8): e95 - 95. [Full Text] [PDF]

				L. Wang, G. A. Manji, J. M. Grenier, A. Al-Garawi, S. Merriam, J. M. Lora, B. J. Geddes, M. Briskin, P. S. DiStefano, and J. Bertin PYPAF7, a Novel PYRIN-containing Apaf1-like Protein That Regulates Activation of NF-kappa B and Caspase-1-dependent Cytokine Processing J. Biol. Chem., August 9, 2002; 277(33): 29874 - 29880. [Abstract] [Full Text] [PDF]