An investigation of the fertilizing characteristics of pyriform-shaped bovine spermatozoa

Two breeding trials were done to determine the effect of pyriform-shaped bovine spermatozoa on fertility. In breeding trial (1), heifers were superstimulated by injecting follicle-stimulating hormone (FSH) and randomly allotted to an affected Bull A (n = 21) or a Control Bull, C (n = 18). Semen from Bull A contained 85% pyriform spermatozoa while that from the Control Bull C contained 91% normal sperm and 2% pyriform spermatozoa. Fertilization rate was lower (P = 0.01) for Bull A (total of 63 ova/embryos; 68.5%) than for the Control Bull, C (total of 81 ova/embryos; 84.4%). In breeding trial (2), 37 oestrus-synchronized heifers were randomly allotted to Bull A (n = 19) or Bull C (n = 18). Pregnancy rates at Day 60 (37% and 61% for Bulls A and C, respectively; P = 0.22) and rate of embryo/fetal loss between Days 22 and 60 of pregnancy (23% and 8% for Bulls A and C, respectively; P = 0.55) were not different. In vitro experiments involving the same Bull A and another Control Bull, B, were designed to explain the mechanism of infertility caused by pyriform sperm. The mean (+/- SEM) number of sperm bound to the zona pellucida was lower (P < 0.05) for Bull A (24.6+/-1.2) than for the Control Bull, B (46.6+/-1.9) and the percentage of zonae penetrated by sperm from Bull A (56.0%) and Bull B (82.8%) was also different (P < 0.05). The percentage of pyriform sperm from Bull A bound to (53%), and penetrating (49%) the zona pellucida was lower (P < 0.05) than that in the inseminate (85%). Although fertilization rates (64.1% and 72.8%) were not different (P = 0.5), cleavage rates (48.2% vs. 74.1%) and morula production rates (24.8% vs. 37.7%) were less (P < 0.05) for Bull A than for Bull B, respectively. In summary, pyriform sperm had reduced capability to bind to and penetrate the zona pellucida, and zygotes (resulting from the fertilization of oocytes by pyriform sperm) appeared to have a reduced ability to initiate cleavage.     

1H NMR investigation on interaction between ibuprofen and lipoproteins

A large number of studies indicate that oxidative modification of plasma lipoproteins, especially low-density lipoprotein (LDL), is a critical factor in initiation and progression of atherosclerosis. We have previously found that ibuprofen (IBP), a potential antioxidant drug to inhibit LDL oxidation, interacted with lipoproteins in intact human plasma. In the present study, we compare the binding affinities of IBP to LDL and HDL (high-density lipoprotein) by (1)H NMR spectroscopy. When IBP is added into the HDL and LDL samples, the - N(+)(CH(3))(3) moieties of phosphatidylcholine (PC) and sphingomyelin (SM) in lipoprotein particles experience the chemical shift up-field drift. Intermolecular cross-peaks observed in NOESY spectra imply that there are direct interactions between ibuprofen and lipoproteins at both hydrophobic and hydrophilic (ionic) regions. These interactions are likely to be important in the solubility of ibuprofen into lipoprotein particles. Ibuprofen has higher impact on the PC and SM head group ( - N(+)(CH(3))(3)) and - (CH(2))(n) - group in HDL than that in LDL. This could be explained by either IBP has higher binding affinity to HDL than to LDL, or IBP induces orientation of the phospholipid head group at the surface of the lipoprotein particles.     

Thyrotropin interaction with high-density lipoproteins

Human high-density lipoproteins (HDL), but not other lipoprotein classes, bind bovine thyrotropin (TSH) with moderately high affinity. Binding of 125I-labeled HDL to TSH has been measured in a solid-phase assay; it is saturable and can be displaced by unlabeled HDL but not by other lipoproteins or bovine serum albumin. The interaction of HDL with TSH has been studied by fluorescence spectroscopy: HDL specifically modifies the fluorescence properties of the biologically active dansyl derivative (DNS, (5-dimethyl-aminonaphtalene-1-sulfonyl) chloride) of TSH (DNS-TSH) causing a 12 nm shift to lower wavelength of the emission maximum, a two-fold increase of the quantum yield and a significant increase of fluorescence polarization. The primary site of TSH binding on the HDL particle is likely to be located on its protein moieties, since other lipoprotein classes, which share similar lipids with HDL, do not bind TSH. 125I-labeled apolipoprotein A-I binds TSH in the solid-phase assay and titration of DNS-TSH with apolipoprotein A-I causes perturbations nearly identical to those observed with intact HDL. One HDL particle has at least 12 binding sites for TSH with an association constant, K = 10(7) M-1 whereas one apolipoprotein A-I molecule binds one or two TSH molecules with an association constant slightly lower than that for HDL (K = 10(6) M-1). The lipid moieties of HDL also appears to be perturbed by the interaction with TSH.     

Cryopreservation of flow-sorted bovine spermatozoa

Experiments were designed to maximize sperm viability after sorting by flow cytometry and cryopreservation. Experiments concerned staining sperm with Hoechst 33342 dye, subsequent dilution, interrogation with laser light, and postsort concentration of sperm. Concentrating sorted sperm by centrifugation to 10 to 20 x 10(6) sperm/ml reduced adverse effects of dilution. Exposing sperm to 150 mW of laser light resulted in lower percentages of progressively motile sperm after thawing than did 100 mW. Sorted sperm extended in a TRIS-based medium had higher postthaw sperm motility after incubation for 1 or 2 h than sperm extended in egg-yolk citrate (EYC) or TEST media, and equilibrating sperm at 5 degrees C for 3 or 6 h prior to freezing was superior to an equilibration time of 18 h. For sorting sperm 4 to 7 h postcollection, it was best to hold semen at 22 degrees C neat instead of at 400 x 10(6)/ml in a TALP buffer with Hoechst 33342. Current procedures for sexing sperm using flow cytometry result in slightly lower postthaw motility and acrosomal integrity compared to control sperm. However, this damage is minor compared to that caused by routine cryopreservation. Fertilizing capacity of flow-sorted sperm is quite acceptable as predicted by simple laboratory assays, and sexed bovine sperm for commercial AI may be available within 2 years.     

The interaction of prostaglandins with human serum lipoproteins

Using high density and low density lipoproteins (HDL and LDL) labeled with fluorescent analogues of phosphatidylcholine or sphingomyelin it was found that low amounts (10^–12 M) of prostaglandins E₁ and F₂ induced different structural rearrangements of the lipoprotein surface, whereas prostaglandins E₂ and F₁ had no effect. The effects of prostaglandin E₁ on HDL were largely paralled by those of this prostaglandin on synthetic recombinants prepared from pure apolipoprotein A₁, phospholipids and cholesterol and were demonstrated to be caused by prostaglandin-apolipoprotein interaction. The interaction resembled that of a ligand with a specific receptor protein because it was specific, reversible, concentration and temperature dependent and saturable. However the retaining capacity of HDL or LDL for prostaglandin E₁ as determined by equilibrium dialysis was very low and a single prostaglandin E₁ molecule was able to induce structural changes in large numbers of discrete lipoprotein particles. To explain this remarkable fact a non-equilibrium model of ligand-receptor interaction is proposed. According to that model in open systems characterized by weak ligand-receptor binding, high diffusion rate of the ligand and long relaxation times which exceed the interval between two successive receptor occupations, the ligand-induced changes will accumulate, resulting in transformation of the system into a new state which may be far away from equilibrium. It is emphasized that the low mobility of lipids constituting the environment of the receptor protein plays a critcal role in this type of signal amplification.It was further demonstrated that the PGE₁-induced changes of the lipoprotein surface resulted in an enhancement of LDL-to-HDL transfer of cholesterol esters and phosphatidylcholine especially in the presence of serum lipid transfer proteins. The acceleration of the interlipoprotein transfer caused by prostaglandin E₁ in turn increases the rate of cholesterol esterification in serum. It is suggested that in such a way prostaglandin E₁ may influence the homeostasis of cholesterol.Abbreviations LDL low density lioproteins - HDL high density lipoproteins - PG prostaglandin - ASM anthrylvinyl-labeled sphingomyelin (N-12-(9-anthryl)-11-trans-dodecanoylsphingosin-1-phosphocholine - APC anthrylvinylphosphatidylcholine (1-radyl-2-[(9-anthryl)-11-transdodecanoyl)-sn-glycerophosphocholine - NAP-SM nitroazidophenyl labeled sphingomyelin (N-[N-(2-nitro-4azidophenyl)-12-aminododecanoyl]-sphingosin-1-phosphocholine) - NAP-PC adizophenyl labeled phosphatidylcholine (1-radyl-2-[N-(2-nitro-4azidophenyl)-12-aminododecanoyl]-sn-glycero-3-phosphocholine - DPPC dipalmitoylphosphatidylcholine - P fluorescence polarization - E parameter of tryptophanyl to ASM resonance energy transfer - LEP lipid-exchange protein     

The interaction of prostaglandins with serum low-density lipoproteins

The interaction of human serum low-density lipoproteins (LDL) with various types of prostaglandins (PG) was studied using equilibrium dialysis, steady-state fluorescence polarization spectroscopy and photolabeling methods. Low concentrations (10(-13)-10(-9) M) of PGE1 and PGF2 alpha were shown to induce specific rearrangements of the lipids on the LDL surface, whereas the closely related PGE2 and PGF1 alpha had no effect. With fluorescent labeled LDL, the PGE1-induced changes of the steady-state fluorescence polarization (P) were shown to be time- and concentration-dependent, saturable and reversible. However, equilibrium dialysis revealed a very low binding capacity of LDL for PGE1 (approx. 1 prostaglandin molecule per 600 LDL particles). Approximately the same PGE1 concentration was sufficient to cause maximal changes of P, to enhance the binding to apolipoprotein B of a photoreactive sphingomyelin analogue inserted into the LDL surface and to alter the thermal phase behavior of the LDL surface lipids. It is proposed that the LDL surface rearrangement caused by prostaglandins is due to the interaction of prostaglandins with apolipoprotein B, resulting in formation of short-lived complexes. The mechanism of this interaction is discussed in terms of the non-equilibrium ligand-receptor interaction model proposed earlier to explain the interaction of prostaglandins with high-density lipoproteins (Bergelson, L.D. et al. (1987) Biochim. Biophys. Acta 921, 182-190). It is suggested that direct prostaglandin-lipoprotein interactions may play a role in the homeostasis of cholesterol.     

Intracytoplasmic sperm injection of bovine oocytes with stallion spermatozoa

Five experiments were designed to study the fertilizability and development of bovine oocytes fertilized by intracytoplasmic sperm injection (ICSI) with stallion spermatozoa. Experiment 1 determined the time required for pronuclear formation after ICSI. Equine sperm head decondensation began 3 h after ICSI; 42% were decondensed 6 h after ICSI. Male pronuclei (MPN) began to form 12 h after ICSI. Female pronuclei (FPN), however, formed as early as 6 h after ICSI. In Experiment 2, ionomycin, ionomycin plus 6-dimethylaminopurine (DMAP), and thimerosal were used to activate ICSI ova. None of the ICSI ova cleaved after treatment with thimerosal. Ionomycin activation after 24 and 30 h of oocyte maturation resulted in 29 and 48% cleavage rates, respectively. Ionomycin combined with DMAP resulted in 49, 6 and 3% cleavage, morula and blastocyst rates, respectively, when oocytes were activated after 24 h maturation. In Experiment 3, rates of cleavage (45-60%) and development to morulae (4-13%) and blastocysts (1-5%) stages following ICSI were not different (P>0.05) among three stallions. Treatment of stallion spermatozoa with ionomycin did not affect cleavage or development of ova fertilized by ICSI. The chromosomal constitution of blastocysts derived from ICSI was bovine, not bovine and equine hybrids. In Experiment 4, to make male and FPN form synchronously, colchicine and DMAP were used for 4 h to inhibit oocytes at metaphase during activation; 63% of oocytes were still at metaphase 8h after ICSI when treated with colchicine, and 50% of sperm nuclei were decondensed. About 18 h after ICSI, 21 and 50% male and FPN had formed, respectively, but cleavage rates were low, and only 1% developed to morulae. In Experiment 5, to test if capacitated equine sperm could fuse with the bovine oolemma, capacitated spermatozoa were injected subzonally (SUZI). Of the 182 SUZI oocytes, 49 (27%) contained extruded second polar bodies. After activation of oocytes with second polar bodies, 44, 22 and 15% developed to 2-, 4- and 8-cell stages, respectively, but development stopped at the 8-cell stage. None of the unactivated oocytes cleaved. In conclusion, equine spermatozoa can decondense and form MPN in bovine oocytes after ICSI, but subsequent embryonic development is parthenogenetic with only bovine chromosomes being found.     

Characterization of the postacrosomal sheath of bovine spermatozoa

A purified head fraction was prepared from bovine epididymal spermatozoa and was utilized to identify the solubility characteristics and major polypeptide components of the postacrosomal sheath. Sperm heads extracted in nonionic-detergent-containing or high-salt-containing solutions retained an intact postacrosomal sheath, but it was readily solubilized by high pH extraction solutions. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed a major polypeptide of 58,000 daltons (58-kD) in the high pH extract solution. Antibodies to the 58-kD polypeptide specifically reacted with the postacrosomal segment by immunofluorescence and by electron microscopic immunohistochemistry were shown to bind the postacrosomal sheath. We conclude that this 58-kD polypeptide is a constituent of the postacrosomal sheath and that its distribution is restricted to the postacrosomal segment.     

The investigation of the interaction between ribavirin and bovine serum albumin by spectroscopic methods

The interaction between ribavirin (RIB) with bovine serum albumin (BSA) has been investigated by fluorescence quenching technique in combination with UV–vis absorption and circular dichroism (CD) spectroscopies under the simulative physiological conditions. The quenching of BSA fluorescence by RIB was found to be a result of the formation of RIB–BSA complex. The binding constants and the number of binding sites were calculated at three different temperatures. The values of thermodynamic parameters ?H, ?S, ?G at different temperatures indicate that hydrophobic and hydrogen bonds played important roles for RIB–BSA association. The binding distance r was obtained according to the theory of FÖrster’s non–radiation energy transfer. The displacement experiments was performed for identifying the location of the binding site of RIB on BSA. The effects of common ions on the binding constant of RIB and BSA were also examined. Finally, the conformational changes of BSA in the presence of RIB were also analyzed by CD spectra and Synchronous fluorescence spectra.     

Hydrophobic interaction of alkanes with liposomes and lipoproteins.

Human serum lipoproteins and egg yolk lecithin liposomes are able to solubilize large amounts of n-hexane and n-octane. At the maximum water solubility of n-octane the mole ratio of alkane to lipoprotein was 65 for high density lipoprotein (holo-HDL) and 900 for low density lipoprotein (holo-LDL). Alkane binding to lipid-free apo-HDL is negligible compared to alkane solubility in holo-HDL. Alkane solubility in the lipoproteins and liposomes is thermodynamically consistent with the simple soution of hydrocarbon in the hydrophobic regions of these particles. The unitary free energies of alkane transfer are similar to values previously observed for detergent micelles but are less favorable by 0.8 kcal/mol from the free energy of transfer to liquid hydrocarbon. It is concluded that the thermodynamics of alkane transfer to the lipoproteins resembles that found for detergent micelles or liposomes rather than that anticipated for an "oil drop" (i.e. liquid hydrocarbon).     

Qualitative and quantitative alterations of bovine serum lipoproteins with ageing

1. Plasma lipoproteins from six calves at 8, 43 and 118 days old, six heifers and six cows were separated by density gradient ultracentrifugation. For each sample lipoproteins bands were visualized by prestained control and characterized by electrophoretic, chemical and morphological analysis. 2. Two resolved bands were detected in the low density lipoprotein fraction (LDL). At an early stage of development, LDLI and LDLII were present with almost equal concentration. With ageing, LDLII became the major fraction of LDL lipoproteins. 3. HDL were isolated as a single band distributed over the range 1.064-1.166 mg/ml in young calf and 1.050-1.152 mg/ml in adult. This progressive decrease of density limits with ageing, associated with a decrease of protein content and an increase of phospholipids and cholesteryl esters content, was consistent with higher HDL particle diameters in adult. 4. With ageing, free cholesterol/esterified cholesterol ratio decreased in LDL fractions and increased in HDL fractions.     

Immunochemical study of the plasma low and high density lipoproteins in Tangier disease

Major disturbances of the lipoproteins in Tangier serum have been investigated using electrophoretic and immunochemical techniques. Previously described anomalies concerning the striking deficiency in HDL and the very low levels of apo A-I and apo A-II in Tangier patients are illustrated and explained. Anomalies concerning the fast LDL of Tangier serum are attributed to different forms of apo B not previously described. These data are strengthened by the features of a 2-dimensional electrophoresis method elaborated in the laboratory which allows apoproteins to separate in the second dimension. These apoproteins are obtained by the delipidation of the lipoproteins fractionated in a first polyacrylamide discontinuous gel. This method clearly shows the distribution of apoproteins in the first lipoprotein track and is in perfect accordance with the new concept of lipoprotein particles.