Zinc is sufficiently abundant within mammalian sperm nuclei to bind stoichiometrically with protamine 2.

Although studies have demonstrated that zinc can bind to sperm nuclear proteins, specifically protamine 2, it has not been shown that the metal is sufficiently abundant inside the sperm nucleus to interact stoichiometrically with these proteins. In this study proton-induced X-ray emission (PIXE) has been used to measure the amount of sulfur and zinc within the nuclei of individual sperm cells to infer the stoichiometry of zinc binding to protamine 2 in six species of mammal: bull, chinchilla, stallion, hamster, human, and mouse (protamine 2 comprises from 0% (bull) to 67% (mouse) of the protamine present in the sperm of these animals). Using the sulfur mass and electrophoretic data on the relative proportion of protamine 1 and protamine 2 in the sperm chromatin of these species, the protamine 1, protamine 2, and total protamine contents within each species sperm nuclei have been determined. The PIXE measurements reveal that the zinc content of the sperm nucleus varies proportionately with the protamine 2 content of sperm chromatin. PIXE analyses of hamster protamines extracted under conditions that appear to at least partially preserve zinc binding also confirm that the majority of the metal is bound to protamine. In five of the species examined, sufficient zinc is present for each protamine 2 molecule to bind one zinc. The results obtained for chinchilla sperm, conversely, indicate the chinchilla protamine 2 molecule may interact differently with zinc. Chinchilla sperm only contain enough zinc for one atom to be bound to two protamine 2 molecules.

Cadmium concentrations in the testes, sperm, and spermatids of mice subjected to long-term cadmium chloride exposure.

BACKGROUND: Exposures to cadmium have been reported to reduce male fertility and there are several hypotheses that suggest how reduced male fertility may result from incorporation of cadmium into sperm chromatin. The purpose of this study was to determine whether mice subjected to long-term intraperitoneal cadmium exposure incorporated cadmium into their sperm chromatin. METHODS: Male mice were exposed to 0.1 mg/kg body weight cadmium in the form of CdCl2 via intraperitoneal injection once per week for 4, 10, 26, and 52 weeks and then sacrificed. The cadmium contents of the liver, testes, pooled sperm, and pooled spermatids from dosed and control animals were determined by atomic absorption spectroscopy. Cadmium and zinc contents in individual sperm and spermatid heads were determined by particle-induced x-ray emission. RESULTS: Atomic absorption spectroscopy revealed that although cadmium accumulated in the liver and testes, cadmium was not detected in pooled sperm or spermatid samples down to minimum detectable limits of 0.02 microg/g dry weight. Particle-induced x-ray emission analyses did not show the presence of cadmium in any sperm or spermatid head down to minimum detectable limits of 15 microg/g dry weight. Particle-induced x-ray emission analyses also demonstrated that phosphorus, sulfur, and zinc concentrations in individual sperm and spermatid heads were not altered by exposure to CdCl2. CONCLUSIONS: Because cadmium was not incorporated into sperm chromatin at levels above 0.02 microg/g dry weight, the data cast doubt on hypotheses that suggest that reduced male fertility may result from incorporation of cadmium into sperm chromatin.

Protein and DNA contents in sperm from an infertile human male possessing protamine defects that vary over time.

Sperm from 2 semen samples collected 6 months apart from an infertile male and 3 semen samples collected over an 18-month period from a fertile human male volunteer have been analyzed for their protamine and DNA content. Hup1M and Hup2b antibodies were used to detect the presence of protamines and protamine precursors in western blots of nuclear proteins isolated from pools of sperm. Phosphorus and sulfur contents, which can be used to estimate the nuclear DNA and protamine contents of sperm from fertile males, were measured within individual sperm heads from each semen sample by particle induced x-ray emission (PIXE). The single-cell data reveal no significant differences in the phosphorus and sulfur contents of sperm heads in the three semen samples obtained from the fertile male. For the initial semen sample produced by the infertile male, Western blot data show a normal complement of protamine 1, small amounts of mature protamine 2, and reveal large amounts of anti-protamine 2 reactive proteins with electrophoretic mobilities similar to protamine 2 precursors. Data from PIXE show elevated levels of sulfur within sperm heads compared with sperm from the fertile male. Western blot data exhibit no evidence of protamines or protamine 2 precursors in the second semen sample produced by the infertile male. Data from PIXE suggest that these sperm are highly deficient in sulfur and protamines. These results show that the degree of maturation of sperm cells present in the semen of some infertile males can vary with time.

DNA and total protamine masses in individual sperm from fertile mammalian subjects.

The total amount of phosphorus and sulfur inside the nuclei of individual bull, stallion, hamster, human, and mouse sperm from fertile subjects has been measured using Particle Induced X-ray Emission (PIXE). Using the sulfur masses, we determined the total protamine (protamine 1 plus protamine 2) mass within the sperm nuclei of each species. Using the phosphorus masses, we determined the DNA mass present within the sperm nuclei of each species. The results reveal that although the relative proportion of protamine 1 to protamine 2 varies among the species examined, the total protamine mass to DNA mass ratio is similar in bull, stallion, hamster, and mouse sperm nuclei. In contrast, mature human sperm nuclei were found to contain significantly less protamine. This observation is consistent with other studies, which suggest that as much as 15% of the DNA in human sperm remain packaged by histones. Using the data obtained for bull sperm, the length of DNA that could be covered by each protamine 1 molecule in bull sperm has been estimated. Making the assumption that the size of the protamine 1 binding site on DNA is similar in the sperm of these species, the length of DNA covered by a single protamine 2 molecule also has been estimated.