The t Complex Distorter 2 Candidate Gene, Dnahc8, Encodes at Least Two Testis-Specific Axonemal Dynein Heavy Chains That Differ Extensively at Their Amino and Carboxyl Termini

AbstractHomozygosity for the t haplotype allele of the testis-specifically expressed axonemal dynein heavy chain (axDHC) gene, Dnahc8, has been linked to male sterility resulting from aberrant sperm motility. However, the near absence of Dnahc8 expression has been associated with male sterility resulting from an early breakdown in sperm flagellar development. Although axDHCs are integral participants in flagellar motility, a role in flagellar morphogenesis has never been attributed to a member of this highly conserved gene family. To gain a better understanding of this presumed novel role for Dnahc8, we have studied the organization and expression of full-length Dnahc8+ and Dnahc8t transcripts. Our results demonstrate the existence of at least two alternatively spliced, testis-specific Dnahc8 mRNAs transcribed from both the + and t alleles. A highly expressed isoform encodes a protein with significant homology nearly throughout to the γ heavy chain of the Chlamydomonas axonemal outer arm dynein, while a more poorly expressed isoform codes for a protein whose sequence diverges significantly from that of other axDHCs at both its N and C termini. While in situ hybridization studies demonstrate that both mRNA species accumulate exclusively in mid to late spermatocytes, each isoform shows spatial independence. Additional experiments demonstrate the existence of a testis-expressed mRNA with no significant open reading frame, a portion of which is antisense to the 5′-untranslated region of the highly divergent Dnahc8 isoform. The cumulative data imply that Dnahc8 may have acquired functional plasticity in the testis through the tightly controlled expression of both typical and unusual isoforms

The mouse t complex distorter/sterility candidate, Dnahc8, expresses a γ-type axonemal dynein heavy chain isoform confined to the principal piece of the sperm tail

AbstractHeterozygosity for a t haplotype (t) in male mice results in distorted transmission (TRD) of the t-bearing chromosome 17 homolog to their offspring. However, homozygosity for t causes male sterility, thus limiting the spread of t through the population at large. The Ca2+-dependent sperm tail curvature phenotypes, “fishhook”, where abnormally high levels of sperm exhibit sharp bends in the midpiece, and “curlicue”, where motile sperm exhibit a chronic negative curving of the entire tail, have been tightly linked to t-associated male TRD and sterility traits, respectively. Genetic studies have indicated that homozygosity for the t allele of Dnahc8, an axonemal γ-type dynein heavy chain (γDHC) gene, is partially responsible for expression of “curlicue”; however, its involvement in “fishhook”/TRD, if any, is unknown. Here we report that the major isoform of DNAHC8 is copiously expressed, carries an extended N-terminus and full-length C-terminus, and is stable and equally abundant in both testis and sperm from +/+ and t/t animals. By in silico analysis we also demonstrate that at least three of the seventeen DNAHC8t mutations at highly conserved positions in wild-type DHCs may be capable of substantially altering normal DNAHC8 function. Interestingly, DNAHC8 is confined to the principal piece of the sperm tail. The combined results of this study suggest possible mechanisms of DNAHC8t dysfunction and involvement in “curlicue”, and support the hypothesis that “curlicue” is a multigenic phenomenon. They also demonstrate that the accelerated “fishhook” phenotype of sperm from +/t males is not directly linked to DNAHC8t dysfunction

PP1γ2 and PPP1R11 Are Parts of a Multimeric Complex in Developing Testicular Germ Cells in which their Steady State Levels Are Reciprocally Related

Mice lacking the protein phosphatase 1 gamma isoforms, PP1γ1 and PP1γ2, are male-sterile due to defective germ cell morphogenesis and apoptosis. However, this deficiency causes no obvious abnormality in other tissues. A biochemical approach was employed to learn how expression versus deficiency of PP1γ2, the predominant PP1 isoform in male germ cells, affects spermatogenesis. Methods used in this study include column chromatography, western blot and northern blot analyses, GST pull-down assays, immunoprecipitation, non-denaturing gel electrophoresis, phosphatase enzyme assays, protein sequencing, and immunohistochemistry. We report for the first time that in wild-type testis, PP1γ2 forms an inactive complex with actin, protein phosphatase 1 regulatory subunit 7 (PPP1R7), and protein phosphatase 1 regulatory subunit 11 (PPP1R11), the latter, a potent PP1 inhibitor. Interestingly, PPP1R11 protein, but not its mRNA level, falls significantly in PP1γ-null testis where mature sperm are virtually absent. Conversely, both mature sperm numbers and the PPP1R11 level increase substantially in PP1γ-null testis expressing transgenic PP1γ2. PPP1R11 also appears to be ubiquitinated in PP1γ-null testis. The levels of PP1γ2 and PPP1R11 were increased in phenotypically normal PP1α-null testis. However, in PP1α-null spleen, where PP1γ2 normally is not expressed, PPP1R11 levels remained unchanged. Our data clearly show a direct reciprocal relationship between the levels of the protein phosphatase isoform PP1γ2 and its regulator PPP1R11, and suggest that complex formation between these polypeptides in testis may prevent proteolysis of PPP1R11 and thus, germ cell apoptosis

Expression of transgenic PPP1CC2 in the testis of Ppp1cc-null mice rescues spermatid viability and spermiation but does not restore normal sperm tail ultrastructure, sperm motility, or fertility

Two isoforms of phosphoprotein phosphatase 1, PPP1CC1 and PPP1CC2, are translated from alternatively spliced transcripts of a single gene, Ppp1cc, and differ only at their extreme C-termini. While PPP1CC1 expression is almost ubiquitous, PPP1CC2 is largely restricted to testicular germ cells and mature spermatozoa. Targeted deletion of Ppp1cc leads to sterility of -/- males due to a combination of gross structural defects in developing spermatids resulting in apoptosis and faulty spermiation. Because PPP1CC2 is the only PP1 isoform that demonstrates high-level expression in wild-type meiotic and postmeiotic male germ cells, we have tested whether its loss in Ppp1cc-/- males is largely responsible for manifestation of this phenotype by expressing PPP1CC2 transgenically in the testis of Ppp1cc-/- mice (rescue mice). Herein, we demonstrate that PPP1CC2 expression in the Ppp1cc-/- testis is antiapoptotic, thus reestablishing spermatid development and spermiation. However, because aberrant flagellar morphogenesis is incompletely ameliorated, rescue males remain infertile. Because these results suggest that expression of PPP1CC2 in developing germ cells is essential but insufficient for normal spermatogenesis to occur, appropriate spatial and temporal expression of both PPP1CC isoforms in the testis during spermatogenesis appears to be necessary to produce structurally normal fertility-competent spermatozoa. © 2009 by the Society for the Study of Reproduction, Inc.Supported by NIH grants HD 38520 to S.V. and HD31164 to S.H.P.Peer Reviewe