Mammalian sperm are incapable of fertilizing eggs immediately after ejaculation; they acquire fertilization capacity after residing in the female tract for a finite period of time. The physiological changes sperm undergo in the female reproductive tract that render sperm able to fertilize constitute the phenomenon of "sperm capacitation." We have demonstrated that capacitation is associated with an increase in the tyrosine phosphorylation of a subset of proteins and that these events are regulated by an HCO 3 ؊ /cAMP-dependent pathway involving protein kinase A. Capacitation is also accompanied by hyperpolarization of the sperm plasma membrane. Here we present evidence that, in addition to its role in the regulation of adenylyl cyclase, HCO 3 ؊ has a role in the regulation of plasma membrane potential in mouse sperm. Addition of HCO 3 ؊ but not Cl ؊ induces a hyperpolarizing current in mouse sperm plasma membranes. This HCO 3 ؊ -dependent hyperpolarization was not observed when Na ؉ was replaced by the nonpermeant cation choline ؉ . Replacement of Na ؉ by choline ؉ also inhibited the capacitation-associated increase in protein tyrosine phosphorylation as well as the zona pellucida-induced acrosome reaction. The lack of an increase in protein tyrosine phosphorylation was overcome by the presence of cAMP agonists in the incubation medium. The lack of a hyperpolarizing HCO 3 ؊ current and the inhibition of the capacitation-dependent increase in protein tyrosine phosphorylation in the absence of Na ؉ suggest that a Na ؉ /HCO 3 ؊ cotransporter is present in mouse sperm and is coupled to events regulating capacitation.Upon ejaculation, mammalian sperm are not able to fertilize; they become fertilization-competent during transit through the female reproductive tract (1). The molecular, biochemical, and physiological changes that occur in sperm while in the female tract are collectively referred to as capacitation. During capacitation, changes in membrane dynamics and properties, enzyme activities, and motility render spermatozoa responsive to stimuli that induce the acrosome reaction and prepare these cells for penetration of the egg vestments prior to fertilization. Mammalian sperm capacitation is also accompanied by the hyperpolarization of the sperm plasma membrane (3). Hyperpolarization is observed as an increase in the intracellular negative charges when compared with the extracellular environment. Although it is not clear how sperm plasma membrane potential is regulated during capacitation, it appears that membrane hyperpolarization may be partially because of an enhanced K ϩ permeability as a result of a decrease in inhibitory modulation of K ϩ channels (3). Recently, Muñ oz-Garay et al. (4) demonstrated with patch clamp techniques that inward rectifying K ϩ channels are expressed in mouse spermatogenic cells and proposed that these channels may be responsible for the capacitation-associated membrane hyperpolarization. Interestingly, Ba 2ϩ blocks these K ϩ channels with an IC 50 similar to that shown to inhibit ...
The active DNA-dependent ATPase A domain (ADAAD), a member of the SWI2/SNF2 family, has been shown to bind DNA in a structure-specific manner, recognizing DNA molecules possessing double-stranded to single-stranded transition regions leading to ATP hydrolysis. Extending these studies we have delineated the structural requirements of the DNA effector for ADAAD and have shown that the single-stranded and double-stranded regions both contribute to binding affinity while the double-stranded region additionally plays a role in determining the rate of ATP hydrolysis. We have also investigated the mechanism of interaction of DNA and ATP with ADAAD and shown that each can interact independently with ADAAD in the absence of the other. Furthermore, the protein can bind to dsDNA as well as ssDNA molecules. However, the conformation change induced by the ssDNA is different from the conformational change induced by stem-loop DNA (slDNA), thereby providing an explanation for the observed ATP hydrolysis only in the presence of the double-stranded:single-stranded transition (i.e. slDNA).
Many members of the SWI2/SNF2 family of adenosine triphosphatases participate in the assembly/disassembly of multiprotein complexes involved in the DNA metabolic processes of transcription, recombination, repair, and chromatin remodeling. The DNA molecule serves as an essential effector or catalyst for most of the members of this particular class of proteins, and the structure of the DNA may be more important than the nucleotide sequence. Inspection of the DNA structure at sites where multiprotein complexes are assembled/disassembled for these various DNA metabolic processes reveals the presence of a common element: a double-stranded to single-stranded transition region. We now show that this DNA element is crucial for the ATP hydrolytic function of an SWI2/SNF2 family member: DNA-dependent ATPase A. We further demonstrate that a domain containing the seven helicase-related motifs that are common to the SWI2/SNF2 family of proteins mediates the interaction with the DNA, yielding specific DNA structural recognition. This study forms a primary step toward understanding the physico-biochemical nature of the interaction between a particular class of DNA-dependent ATPase and their DNA effectors. Furthermore, this study provides a foundation for development of mechanisms to specifically target this class of DNAdependent ATPases.DNA recognition and the ensuing ATP hydrolysis by DNAdependent ATPases are common denominators of a number of different macromolecular assembly/disassembly processes that are required for DNA metabolic events such as chromatin remodeling, replication, repair, recombination, and transcription. There are a variety of types of known nucleic acid-modifying enzymes that use the energy released by ATP hydrolysis to produce changes in a nucleic acid substrate (i.e. helicases, nucleases, topoisomerases, ligases, and recombinases). However, there are a few nucleic acid-dependent ATPases where the nucleic acid is not obviously modified and consequently does not appear to be a substrate for the enzyme. In these cases, the nucleic acid is generally regarded as an effector of the enzymatic activity. DNA-dependent ATPase A hydrolyzes ATP only in the presence of a DNA effector, without apparent modification of the effector. Originally isolated from calf thymus tissue, ATPase A is a 105-kDa protein that undergoes proteolysis to yield two smaller polypeptides with estimated molecular masses of 68 and 83 kDa (1). All three polypeptides possess ATPase activity that is manifested only in the presence of DNA. Initial studies with the 68-kDa polypeptide indicated that the protein is maximally active in the presence of DNA effectors possessing primer-template junctions (i.e. doublestranded to single-stranded transition). This effector preference is reminiscent of the gp44⅐62 and gp45 protein complex from T4 bacteriophage (2, 3). The gp44⅐62 protein complex hydrolyzes ATP in the presence of primer-template DNA, with the energy release being coupled to the loading of a gp45 sliding clamp complex onto DNA, thereby incre...
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