A-kinase anchoring proteins (AKAPs) tether cyclic AMP-dependent protein kinases and thereby localize phosphorylation of target proteins and initiation of signal-transduction processes triggered by cyclic AMP. AKAPs can also be scaffolds for kinases and phosphatases and form macromolecular complexes with other proteins involved in signal transduction. Akap4 is transcribed only in the postmeiotic phase of spermatogenesis and encodes the most abundant protein in the fibrous sheath, a novel cytoskeletal structure present in the principal piece of the sperm flagellum. Previous studies indicated that cyclic AMP-dependent signaling processes are important in the regulation of sperm motility, and gene targeting was used here to test the hypothesis that AKAP4 is a scaffold for protein complexes involved in regulating flagellar function. Sperm numbers were not reduced in male mice lacking AKAP4, but sperm failed to show progressive motility and male mice were infertile. The fibrous sheath anlagen formed, but the definitive fibrous sheath did not develop, the flagellum was shortened, and proteins usually associated with the fibrous sheath were absent or substantially reduced in amount. However, the other cytoskeletal components of the flagellum were present and appeared fully developed. We conclude that AKAP4 is a scaffold protein required for the organization and integrity of the fibrous sheath and that effective sperm motility is lost in the absence of AKAP4 because signal transduction and glycolytic enzymes fail to become associated with the fibrous sheath.
We have identified cDNAs representing three hexokinase mRNAs (Hk1-sa, Hk1-sb, Hk1-sc) by screening mouse spermatogenic cell cDNA libraries with a mouse hepatoma cell line hexokinase (Hk1) cDNA [Arora KK, Fanciulli M, Pederson PL. J Biol Chem 1990; 265:6481-6488]. Although all three cDNAs show 99% identity to the somatic Hk1 cDNA sequence throughout most of their coding region, they differ from this sequence at the 5' end. They contain a common spermatogenic cell-specific sequence and a sequence unique to each cDNA immediately 5' to the common domain. However, they lack the porin-binding domain (PBD) present in this region of Hk1, used for binding to a pore-forming protein in the outer mitochondrial membrane. These observations appear to support a model proposed by others for hexokinase gene evolution in mammals. In addition, we found that Hk1-sb has an internal sequence that is not present in Hk1, Hk1-sa, or Hk1-sc. Moreover, Hk1-sa and Hk1-sb transcripts are developmentally expressed in mouse spermatogenic cells. Hk1-sa mRNA is first expressed during meiosis and continues to be present in postmeiotic germ cells, while the more abundant Hk1-sb mRNA is detected only in postmeiotic germ cells. These and other findings suggest that enzymes encoded by Hk1-sa, Hk1-sb, and Hk1-sc are present only in spermatogenic cells.
The fibrous sheath is a major cytoskeletal structure in the principal piece of the mammalian sperm flagellum. We have cloned a cDNA and used it to characterize the expression of mRNA for a mouse sperm fibrous sheath protein. Peptides from a tryptic digest of fibrous sheath proteins were separated by HPLC and a 31 amino acid sequence was obtained from one of the peptides. Through the use of degenerate oligonucleotide polymerase chain reaction (PCR) primers predicted from this sequence, an 80-bp product was amplified from mouse testis first-strand cDNA. This was utilized as a probe to isolate a 2.9-kb cDNA clone from a mouse round spermatid cDNA library. Sequence analysis of the cDNA clone showed that it encodes a protein with an open reading frame of 849 amino acids and includes the original peptide sequence. The predicted protein has a molecular weight of 93,795 and contains 32 cysteine residues and 32 potential phosphorylation sites. It has no significant homology with other known cytoskeletal proteins. Northern blot analysis detected an mRNA of approximately 3 kb that was abundant in round spermatids of the mouse and in testes from six other mammalian species, but not in twelve somatic tissues from the mouse. In situ hybridization analysis indicated that the mRNA is first detected in step 1-6 spermatids, is most abundant in step 8-12 spermatids, and decreases in amount in step 13-15 spermatids, suggesting that expression of the mRNA occurs in the postmeiotic phase of spermatogenesis.(ABSTRACT TRUNCATED AT 250 WORDS)
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