Federation proceedings最新文献

The mutually exclusive expression of L3T4 and Lyt-2 on murine T cells and the correlation of their expression to the major histocompatibility complex (MHC) restriction of the T cell antigen receptor (Ti) have led to the hypothesis that these surface molecules are related to recognition of class II and class I MHC antigens, respectively. It has been suggested that these T cell surface molecules interact with nonpolymorphic determinants on MHC antigens. We have studied the role of L3T4 in activation of an H-2Dd-specific T cell hybridoma. This novel hybridoma allowed the separate evaluation of the specificities of Ti and L3T4 and the examination of their roles in T cell activation. Antibody-blocking experiments have demonstrated that L3T4 was involved in triggering this T cell hybridoma only if the antigen-bearing cell expressed Ia. The apparent requirement for an L3T4-Ia interaction reflected the amount of available H-2Dd antigen. It appears that the L3T4-Ia interaction influences T cell activation during suboptimal antigenic stimulation. We have begun to examine the role of L3T4 in lectin and anti-Ti monoclonal antibody stimulation of the same T cell hybridoma. These experiments have suggested a distinct role for L3T4 in the absence of Ia, as a mediator of a negative signal for activation.

Historically, functional hyperemia has been viewed largely as an interaction between a parenchymal cell and its associated microvasculature. Locally released metabolites have been thought to produce relaxation of the smooth muscle and a vasodilation that increases blood flow in proportion to metabolic need. This symposium report presents evidence from a variety of disciplines and a number of different types of biological preparations that demonstrates that functional hyperemia is a complex process involving several classes of microvessels including capillaries, arterioles, and small arteries. These vessels do not function independently but are coordinated by a complex set of interrelations involving at least three different modes of interaction between parenchymal cells and the various segments of the vascular bed. These are local metabolic effects, propagated effects extending over long segments of the vasculature, and flow-dependent vasodilation induced by local changes in blood flow. In addition to these acute responses to metabolic demand it appears that tissues may be capable of more long-term structural alterations of the arterial and arteriolar network in response to sustained changes in the relationship between supply and demand. The vascular bed appears to be able to adapt either by increasing the maximal anatomic diameter of the large arteries or by inserting new arterioles into the parenchyma. Thus, classical functional hyperemia appears to be but one manifestation of a multifaceted process leading to highly coordinated responses of many vascular elements, resulting finally in vascular patterns that are optimized to meet parenchymal cell demands.

Physical constraints on ruminal digestion have received concentrated research attention in the past 10 years. With scanning electron microscopy, microbial attack and digestion of forage components in the rumen have been observed. Limits to passage through the digestive tract have been explored with digesta flow markers and particle-sizing devices. Diet composition analysis has been simplified by near-IR reflectance. NMR procedures, and histological indexing. Rumen microbial function and genetics are being examined by new procedures and genetically altered microbes are being used for production of specific nutrients. Isolated microbial enzymes are being used in feed analysis. The site of digestion in vivo has received detailed attention with new cannula designs, digesta flow markers, and constitutive microbial markers. Ruminants are being maintained by intragastric or i.v. infusion of purified nutrients to quantitate nutrient requirements. Static and dynamic models of digestive function are aiding in the interpretation of research data. Unfortunately, many new procedures have not been critically standardized against traditional methods. The complexity of certain new techniques and models complicates critical review, publication, and comprehension of research results. The most important laboratory tool for increasing research knowledge is still the alert, fertile human imagination.

Exogenous natural and synthetic estrogenic and androgenic steroid hormones are used commercially to stimulate metabolic processes associated with increased rate and efficiency of body growth in ruminants. However, mechanisms of action of steroid hormone-induced effects on metabolism are relatively unknown. Application of peptide hormones to muscle growth, fat deposition, and lactation has lagged because of lack of sufficient quantities of the hormones. However, with recombinant DNA technology synthesis of large quantities of peptide hormones is now feasible. Most efforts have focused on growth hormone (GH), growth hormone-releasing factor (GRF), and prolactin (PRL) effects on lactation. For example, administration of GH or GRF stimulates yields of milk, milk fat, protein, and lactose as much as 41% in cattle. The mechanism of GH action probably involves somatomedin C acting at extramammary sites and (or) directly at the mammary cell. PRL is lactogenic but has no significant effect on established lactation in cattle. Daily exposure of cattle to 16 h light and 8 h of darkness stimulates milk yield and body growth and reduces fat accretion in the carcass, but the hormonal signals responsible for these photoperiod-induced responses are unknown. Photoperiod manipulations are relatively easy to apply to ruminants, but development of suitable delivery systems for animals will greatly enhance application of peptide hormones to further studies of metabolism as well as commercial livestock production systems.

Most nutrition research is related to rates of physiological processes. Information about those processes can be gained by in vivo kinetic techniques; however, many nutritionists are hesitant to use in vivo kinetics. The two basic in vivo kinetic techniques are single injection and continuous infusion of tracer into a pool of tracee. Either technique can form the basis for multiple-pool kinetics, or modeling. Solving a multiple-pool system can provide flow rates of substances between metabolic pools and is valuable for understanding a particular metabolic pathway or process. In vivo kinetic techniques can be valuable in understanding mechanisms whereby partitioning agents affect the distribution of nutrients, especially protein and fat, in food-producing animals. In vivo kinetics is a valuable tool for nutrition research and should be used more frequently.

Muscle cell culture techniques have been used for several years in research on muscle growth and development. Several types of culture systems have been devised, including primary cultures from embryonic or postnatal muscle and myogenic cell lines. In addition, serum-free and serum-containing media have been developed to address specific muscle development questions. Many of these questions center around muscle cell differentiation and muscle cell physiology; and, more recently, muscle cell cultures have been used as bioassay tools for examining growth physiology in domestic animals. In our laboratory, skeletal muscle satellite cells have been studied in vitro to evaluate the effect of several protein hormones and growth factors on satellite cell proliferation and differentiation. Of the hormones examined, only the insulin-like growth factors/somatomedins and fibroblast growth factor have been shown to have a stimulatory effect on proliferation that could be physiologically significant. None of the major anterior pituitary hormones interacted directly with satellite cells to stimulate proliferation. With advances in serum-free medium formulations and cell separation techniques, more information can be obtained from experiments with muscle cell cultures. With appropriate design and interpretation, our knowledge of muscle growth in domestic animals will be expanded.