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Query: UNIPROT:P01034 (
cystatin C
)
3,397
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The cystatin superfamily of cysteine protease inhibitors consists of three major families, including the stefins, cystatins and kininogens. However, the recent identification of several genes that possess sequence similarity with the cystatins but have different gene or protein structures indicates that several new cystatin families or subgroups of families might exist. We previously identified the cystatin-related
epididymal
spermatogenic (Cres) gene, which is related to the family 2 cystatins but exhibits highly tissue-specific expression in the reproductive tract. In the studies presented here, an analysis of gene structure as well as chromosomal mapping studies suggest that the Cres gene might represent a new subgroup within the family 2 cystatins. Although the Cres gene possesses an additional exon encoding 5' untranslated sequences, its coding exons are similar in size to the three coding exons of the cystatin family 2 genes, and the Cres exon/intron splice junctions occur in identical locations as in the
cystatin C
gene. Furthermore, chromosomal mapping studies show that the Cres gene co-segregates with the
cystatin C
gene on mouse chromosome 2. Similar to the cystatin family 2 proteins, the Cres protein possesses the type A and B disulphide loops that are necessary for cystatin folding. Interestingly, Cres protein also possesses half of a type C disulphide loop. Although probably related to the cystatin genes, the Cres gene is distinct in that its promoter contains consensus motifs typical of regulated genes. Finally, reverse transcriptase-mediated PCR studies and the identification of new Cres cDNA clones indicate that the Cres mRNA is alternatively spliced, resulting in two Cres mRNAs that might be involved in the regulation of Cres function.
...
PMID:Structure, alternative splicing and chromosomal localization of the cystatin-related epididymal spermatogenic gene. 1022 62
The CRES (cystatin-related
epididymal
spermatogenic) protein defines a new subgroup in the family 2 cystatins of the cystatin superfamily of cysteine protease inhibitors. However, unlike the ubiquitous expression of
cystatin C
, the Cres gene is preferentialy expressed in postmeiotic germ cells, the proximal caput epididymidis, and anterior pituitary gonadotrophs. Furthermore, CRES protein lacks two of the three consensus sites necessary for the cystatin inhibition of C1 cysteine proteases. Therefore, CRES may perform unique and tissue-specific functions in the reproductive and neuroendocrine systems. In the present review, we describe our studies on: 1. the Cres gene promoter and the transcriptional regulatory protein and their associated DNA binding sites that may be important for tissue-specific expression; and 2. the biochemical function of CRES protein. In brief, Northern blot, gel shift analyses, and transient transfection assays demonstrated that the C/EBP beta (CCAAT/enhancer binding protein) transcription factor is the predominant C/EBP family member expressed in the epididymis and gonadotroph cells and is necessary for high levels of Cres expression in these two tissues. In other studies, analyses of transgenic mice expressing a CAT reporter gene driven by 1.6 kb of Cres promoter revealed CAT mRNA and protein only in the germ cells. These studies suggest that the 1.6 kb of Cres 5' flanking sequence contains the required DNA elements for expression in the testis, but lacks the elements to correctly target expression of the reporter gene in the epididymis. Alternatively, repressor elements may be present. Finally, in vitro protease assays were performed to determine if CRES functions as a protease inhibitor. In contrast to cystain C, CRES did not inhibit the C1 cysteine protease papain but rather inhibited at nanomolar concentrations the serine protease PC2, a prohormone processing enzyme. Therefore, CRES is a new cross-class inhibitor that may regulate PC2 of PC2-like proteases and suggests a role for CRES in the regulation of prohormone and proprotein processing.
...
PMID:[Cres (cystatin-related epididymal spermatogenic) gene regulation and function]. 1247 14
The cystatin-related
epididymal
spermatogenic (CRES) protein is related to the family 2 cystatins of the cystatin superfamily of cysteine protease inhibitors. However, CRES lacks sequences important for cysteine protease inhibitory activity and is specifically expressed in reproductive and neuroendocrine tissues. Thus, CRES is distinct from cystatins and may perform unique tissue-specific functions. The purpose of the present study was to determine whether CRES functions as a protease inhibitor in in vitro assays. In contrast to mouse recombinant
cystatin C
, recombinant CRES did not inhibit the cysteine proteases papain and cathepsin B, suggesting that it probably does not function as a typical cystatin. CRES, however, inhibited the serine protease prohormone convertase 2 (PC2), a protease involved in prohormone processing in the neuroendocrine system, whereas
cystatin C
showed no inhibition. CRES did not inhibit subtilisin, trypsin, or the convertase family members, PC1 and furin, indicating that it selectively inhibits PC2. Kinetic analysis showed that CRES is a competitive inhibitor of PC2 with a K(i) of 25 nM. The removal of N-terminal sequences from CRES decreased its affinity for PC2, suggesting that the N terminus may be important for CRES to function as an inhibitor. These studies suggest that CRES is a cross-class inhibitor that may regulate proprotein processing within the reproductive and neuroendocrine systems.
...
PMID:The cystatin-related epididymal spermatogenic protein inhibits the serine protease prohormone convertase 2. 1258 66
The
epididymal
lumen represents a unique extracellular environment because of the active sperm maturation process that takes place within its confines. Although much focus has been placed on the interaction of
epididymal
secretory proteins with spermatozoa in the lumen, very little is known regarding how the complex
epididymal
milieu as a whole is maintained, including mechanisms to prevent or control proteins that may not stay in their native folded state following secretion. Because some misfolded proteins can form cytotoxic aggregate structures known as amyloid, it is likely that control/surveillance mechanisms exist within the epididymis to protect against this process and allow sperm maturation to occur. To study protein aggregation and to identify extracellular quality control mechanisms in the epididymis, we used the cystatin family of cysteine protease inhibitors, including cystatin-related
epididymal
spermatogenic and
cystatin C
as molecular models because both proteins have inherent properties to aggregate and form amyloid. In this chapter, we present a brief summary of protein aggregation by the amyloid pathway based on what is known from other organ systems and describe quality control mechanisms that exist intracellularly to control protein misfolding and aggregation. We then present a summary of our studies of cystatin-related
epididymal
spermatogenic (CRES) oligomerization within the
epididymal
lumen, including studies suggesting that transglutaminase cross-linking may be one mechanism of extracellular quality control within the epididymis.
...
PMID:Extracellular quality control in the epididymis. 1758 87
CRES (cystatin-related
epididymal
spermatogenic), a member of the cystatin superfamily of cysteine protease inhibitors, is expressed in the epididymis and spermatozoa, suggesting specialized roles in reproduction. Several cystatin family members oligomerize, including
cystatin C
that forms amyloid deposits associated with cerebral amyloid angiopathy. Our studies demonstrate that CRES also forms oligomers. Size exclusion chromatography revealed the presence of multiple forms of CRES in the
epididymal
luminal fluid, including SDS-sensitive and SDS-resistant high molecular mass complexes. In vitro experiments demonstrated that CRES is a substrate for transglutaminase and that an endogenous transglutaminase activity in the
epididymal
lumen catalyzed the formation of SDS-resistant CRES complexes. The use of a conformation-dependent antibody that recognizes only the oligomeric precursors to amyloid, negative stain electron microscopy, and Congo Red staining showed that CRES adopted similar oligomeric and fibrillar structures during its aggregation as other amyloidogenic proteins, suggesting that CRES has the potential to form amyloid in the
epididymal
lumen. The addition of transglutaminase, however, prevented the formation of CRES oligomers recognized by the conformation antibody by cross-linking CRES into an amorphous structure. We propose that transglutaminase activity in the
epididymal
lumen may function as a mechanism of extracellular quality control by diverting proteins such as CRES from the amyloidogenic pathway.
...
PMID:Oligomerization and transglutaminase cross-linking of the cystatin CRES in the mouse epididymal lumen: potential mechanism of extracellular quality control. 1785 42
Cystatin-related
epididymal
spermatogenic (CRES) protein, a member of the cystatin superfamily of cysteine protease inhibitors (also known as CST8), exhibits highly specific, age-dependent expression in mouse testis and epididymis. The CRES protein possesses four highly conserved cysteine residues which govern the overall conformation of the cystatins through the formation of two disulfide bonds. Previous studies have revealed that other cystatin family members, such as
cystatin 3
and cystatin 11, show antibacterial activity in vitro. This prompted us to investigate the potential antimicrobial activity of the CRES protein. Colony forming assays and spectrophotometry were used to investigate the effects of recombinant CRES protein on Escherichia coli (E. coli) and Ureaplasma urealyticum (Uu), respectively, in vitro. After incubation of E. coli with CRES recombinant protein fused with glutathione-S-transferase (GST), a substantial decrease in colony forming units was observed, and the effect was dose and time dependent. Furthermore, it took longer for Uu to grow to plateau stage when incubated with GST-CRES recombinant protein compared with the control GST. The antibacterial and Anti-Uu activities were not impaired when the cysteine residues of CRES protein were mutated, indicating that the antimicrobial effect was not dependent on its disulfide bonds. Functional analysis of three CRES polypeptides showed that the N-terminal 30 residues (N30) had no antimicrobial activity while N60 showed similar activity as full-length CRES protein. These results suggest that the active center of CRES protein resides between amino acid residues 31 and 60 of its N-terminus. Mechanistically, E. coli membrane permeabilization was increased in a dose-dependent manner, and macromolecular synthesis was inhibited on treatment with GST-CRES. Together, our data on the antimicrobial activities of CRES protein suggest that it is a novel and innate antimicrobial protein which protecting the male reproductive tract against invading pathogens.
...
PMID:Antimicrobial activity and molecular mechanism of the CRES protein. 2318 54
Hereditary
cystatin C
amyloid angiopathy is an autosomal dominant disorder in which a variant form of
cystatin C
(L68Q) readily forms amyloid deposits in cerebral arteries in affected individuals resulting in early death. L68Q protein deposits in human
cystatin C
amyloid angiopathy patients have also been found in tissues outside of the brain including the testis, suggesting possible effects on fertility. Heterozygous transgenic mice (L68Q) that express the human L68Q variant of
cystatin C
under the control of the mouse
cystatin C
promoter were unable to generate offspring, suggesting the presence of L68Q
cystatin C
amyloid affected sperm function. In vitro studies showed that
epididymal
spermatozoa from L68Q mice were unable to fertilize oocytes and exhibited poor sperm motility. Furthermore, spermatozoa from L68Q mice exhibited reduced cell viability compared with wild type (WT) spermatozoa and often were detected in large agglutinated clumps. Examination of the
epididymal
fluid and spermatozoa from L68Q mice showed increased levels and distinct forms of
cystatin C
amyloid that were not present in WT mice. The addition of
epididymal
fluid from L68Q mice to WT spermatozoa resulted in a recapitulation of the L68Q phenotype in that WT spermatozoa showed reduced cell viability and motility compared with WT spermatozoa incubated in
epididymal
fluid from WT mice. L68Q
epididymal
fluid that was depleted of
cystatin C
amyloids, however, did not impair the motility of WT spermatozoa. Taken together these studies suggest that amyloids in the
epididymal
fluid can be cytotoxic to the maturing spermatozoa resulting in male infertility.
...
PMID:Fertility defects in mice expressing the L68Q variant of human cystatin C: a role for amyloid in male infertility. 2450 Jul 19
Immature spermatozoa undergo series of events in the epididymis to acquire motility and fertilizing ability. These events are a direct result of exposure to, and interaction with, the luminal environment created by the
epididymal
epithelium. The three conventional regions of the epididymis namely; caput, corpus and cauda have been identified to play specific roles in the
epididymal
maturation process of the spermatozoa; their respective roles have been associated with specific gene expression patterns that account for the composition of the luminal fluid that bathe the spermatozoa as they transit through the
epididymal
lumen and ensure their maturation. The identification of genes expressed in a region-specific manner provides valuable insight into the functional differences among the regions. Microarray technology has previously been employed in region-specific gene expression studies using the epididymis as a model in different species such as mouse, rat, boar and human. However, to characterize gene expression in the different regions of the epididymis, RNA-seq analysis was used in our study to examine gene expressions in the caput, corpus, and cauda of yak epididymis. Comparative transcriptomic analysis was performed between region pairs in the order; caput vs corpus, caput vs cauda and corpus vs cauda. DEGs among the various region pairs were detected and functional analysis were performed for the detected DEGs. Overall, the caput vs cauda epididymidis pair produced the highest number of DEGs (49.4%) while the corpus vs cauda pair produced the least number of DEGs (19.3%). The caput segment demonstrated relatively high expression of Sal1, LCN6, PTDS, DEFB109, DEFB 119, DEFB 123, SPAG11, PROC,
CST3
, ADAM28, KCNJ12 and SLC13A2; corpus epididymis demonstrated relatively high expression of MAN2B2, ELP, ZFYVE21, GLB1L, BMP4, DEFB125, PPP1R10, RIOX2, TKDP1, DEFB106A, NPBWR1 and SLC28A1; and the cauda epididymis, demonstrated relatively high expressions of MCT7, PAG4, OAS1, TGM3 and PRSS45. Gene Ontology results showed that DEGs in the caput vs corpus and corpus vs cauda pairs were mostly enriched in the cell/cell part GO term. On the other hand, DEGs in the caput vs cauda pair was were mostly enriched in the cellular process term. KEGG pathway annotation was also performed for DEGs among the various groups. AMPK signaling pathway, which is characterized by the ratio between cellular AMP and ATP and also determines cellular energy state, was selected from among the top five KEGG pathways for DEGs in the caput vs corpus pair. Our results showed that some down-regulated DEGs in the caput and corpus pair such as HN4a, eEF2K and CFTR were present and played significant roles in the AMPK signaling pathway. In the corpus vs cauda pair, our results showed that up-regulated DEGs such as XDH, TRMP2 and ENTPD were involved in the purine metabolism KEGG pathway, which was among top five KEGG pathways for DEGs in this pair. Pentose phosphate pathway functions in antioxidation to protect both the spermatozoa and epididymis from oxidative damage; it was among top five KEGG pathways for DEGs in the caput vs cauda pair. Our results also showed that down-regulated genes in the caput vs cauda pair such as TALDO1 was found to be involved in the Pentose phosphate pathway. The significance of the upregulated and downregulated genes on the pathways were elucidated. SAL1, which showed high expression in the caput, had previously not been demonstrated in the epididymis, needs further investigation to establish its unique role in the yak epididymis.
...
PMID:Region-specific gene expression in the epididymis of Yak. 3140 23
