Showing papers in "Annals of the New York Academy of Sciences in 1996"

Mechanism of action of camptothecin

Abstract: Camptothecin (CPT) class of compounds has been demonstrated to be effective against a broad spectrum of tumors. Their molecular target has been firmly established to be human DNA topoisomerase I (topo I). CPT inhibits topo I by blocking the rejoining step of the cleavage/religation reaction of topo-I, resulting in accumulation of a covalent reaction intermediate, the cleavable complex. The primary mechanism of cell killing by CPT is S-phase-specific killing through potentially lethal collisions between advancing replication forks and topo-I cleavable complexes. Collisions with the transcription machinery have also been shown to trigger the formation of long-lived covalent topo-I DNA complexes, which contribute to CPT cytotoxicity. Two novel repair responses to topo-I-mediated DNA damage involving covalent modifications of topo-I have been discovered. The first involves activation of the ubiquitin/26S proteasome pathway, leading to degradation of topo-I (CPT-induced topo-I downregulation). The second involves SUMO conjugation to topo-I. The potentials roles of these new mechanisms for repair of topo-I-mediated DNA damage in determining CPT sensitivity/resistance in tumor cells are discussed.

Role of matrix metalloproteinases in abdominal aortic aneurysms

Abstract: Considerable progress has been made toward characterizing the enzymes and proteolytic events that occur in established human abdominal aortic aneurysms (AAA). Through studies involving a number of different laboratories and various experimental approaches, enzymes of the matrix metalloproteinase (MMP) family have consistently emerged as important molecular participants in aneurysm disease. The finding that elastolytic MMPs, particularly MMP-9 and MMP-2, are expressed and produced in increased amounts in human aneurysm tissue, has led to the possibility that these enzymes might serve as rational targets for pharmacotherapy in this disease. Recent studies using MMP-inhibiting tetracycline derivatives in the elastase-induced rodent model of AAA indicate that metalloproteinase suppression is a feasible and successful approach in the experimental setting. The definitive proof-of-principle for the therapeutic efficacy of anti-MMP or other anti-proteinase strategies to limit the growth of small AAA, however, will remain unknown until specifically tested in clinical trials.

The Role of APP Processing and Trafficking Pathways in the Formation of Amyloid β-Proteina

Abstract: The amyloid beta-protein (A beta) is a proteolytic fragment of the beta-amyloid precursor protein (beta APP). We previously reported the constitutive secretion of A beta peptides from a variety of cells expressing beta APP under normal culture conditions. These endogenously produced A beta peptides have heterogeneous N- and C-termini that vary as a function of beta APP missense mutations. Treatment of A beta-secreting cells with agents that alter intravesicular pH showed that an acidic compartment is required for proper A beta generation. One such compartment appears to be the endosome. Immunolabeling of cell-surface beta APP in living neurons and non-neuronal cells directly demonstrated the endocytosis of the protein and its rapid recycling (within 5-10 minutes) to the cell surface, as well as the trafficking of some beta APP to lysosomes. Expression of beta APP with various deletions of the cytoplasmic domain, including the NPTY motif, leads to decreased internalization and an associated decrease in the production of A beta peptides that begin at the usual asp1 start site. These and other data suggest that A beta production begins with cleavage of beta APP by a still unknown protease(s) (beta-secretase[s]) at the met-asp bond proceeding the A beta N-terminus and that this occurs in part in early endosomes. To characterize the substrate requirements of beta-secretase, beta APP was mutagenized by placing stop codons within or at the end of the transmembrane domain or substituting other amino acids for the wild-type met and asp at the P1 and P1' positions. These experiments showed that proper beta-secretase cleavage requires the precursor to be membrane-anchored and is highly sequence specific; most substitutions at met or asp substantially decrease A beta production. Analogous mutagenesis experiments around the A beta C-terminus revealed that the unknown protease(s) cleaving here ("gamma-secretase[s]") does not show such specificity. Cells secreting A beta may also be useful for examining the critical issue of the aggregation of A beta into its neurotoxic polymeric form under physiological conditions. In this regard, we have found that beta APP-expressing CHO cells show aggregation of > or = 10-20% of their secreted A beta peptides into SDS-stable dimers, trimers and sometimes tetramers under normal culture conditions. The identity of these small multimers was confirmed by extensive immunochemical characterization and radiosequencing. They are present at approximately 100-500 pM levels in conditioned medium of CHO transfectants. Using this endogenous A beta aggregating system, we have begun to examine variables that influence aggregation and compounds which may retard it. In conclusion, studies of the regulation of A beta production and aggregation in cell culture can provide information under physiological conditions that can complement analyses of these processes in vivo.

The peroxisome proliferator-activated receptors: ligands and activators.

Abstract: PPAR alpha and PPAR gamma represent related but distinct members of the nuclear receptor superfamily. PPAR alpha signaling is modulated by long-chain fatty acids, whereas PPAR gamma ligands are potent antidiabetic agents.

The flight from science and reason

Abstract: "Evidence of a flight from reason is as old as human record-keeping: the 'fact' of it certainly goes back an even longer way. Flight from science specifically, among the forms of rational inquiry, goes back as far as science itself...But rejection of reason is now a pattern to be found in most branches of scholarship and in all the learned professions."--from the introduction In the widely acclaimed 'Higher Superstition: The Academic Left and Its Quarrels with Science,' Paul R. Gross and Norman Levitt offered a spirited response to the "science bashers", raising serious questions about the growing criticism of scientific practice from humanists and social scientists on the academic left. Now, in 'The Flight from Science and Reason,' Gross and Levitt are joined by Martin W. Lewis to bring together a diverse and distinguished group of scholars, scientists, and experts to engage these questions from a wide variety of perspectives. The authors take on critics of science whose views range from moderate to extreme, from social constructivists to deconstructionists, from creationists and feminists to Afro-centrists. They discuss the rise of "alternative medicine" and radical environmentalism (here skewered as "ecosentimentalism"). They explain why the "uncertainty principle" does not work as a metaphor for ambiguity, and why "chaos theory" cannot be invoked without an understanding of mathematics. Throughout, they grapple with the paradox inherent in arguing with opponents who contend that reason itself, and thus logic, is suspect. 'Distributed for the New York Academy of Sciences'

Tau protein and the neurofibrillary pathology of Alzheimer's disease.

Abstract: Abundant neurofibrillary tangles, neuropil threads and senile plaque neurites constitute the neurofibrillary pathology of Alzheimer's disease. They form in the nerve cells that undergo degeneration in the disease, in which their regional distribution correlates with the degree of dementia. Each lesion contains the paired helical filament (PHF) as its major component. PHFs are composed of the microtubule-associated protein tau in a hyperphosphorylated state. PHF-tau is hyperphosphorylated on all six adult brain isoforms. As a consequence, tau is unable to bind to microtubules and is believed to self-assemble into the PHF. Several candidate protein kinases and protein phosphatases have been identified through in vitro experiments.

PPAR tissue distribution and interactions with other hormone-signaling pathways

Abstract: Reference NCEM-REVIEW-1996-006doi:10.1111/j.1749-6632.1996.tb18619.xView record in PubMed Record created on 2009-04-02, modified on 2017-05-12

Autonomic nervous system factors underlying disinhibited, antisocial, and violent behavior. Biosocial perspectives and treatment implications.

Abstract: This paper reviews the autonomic psychophysiological correlates of antisocial and aggressive behavior in children and adolescents, outlines a biosocial perspective, and draws implications for treatment and prevention. Findings of studies on resting skin conductance and heart rate indicate that antisocial individuals are characterized by underarousal; these findings suggest that aggressive children may be stimulation seekers who are relatively fearless. Autonomic underarousal also typifies infants and young children with a disinhibited temperament that is thought to be a predisposition to juvenile delinquency and adult aggressive behavior. Deficits in the orienting response, a measure of attention allocation, also predisposes to later antisocial and criminal behavior. Initial studies have shown that particularly high levels of orienting, arousal, and conditionability may protect against crime development in those predisposed to such an outcome. From a biosocial standpoint, it is hypothesized that the psychophysiological correlates of antisocial and violent behavior may be greatest in those from more benign home backgrounds where the psychosocial push forward is relatively weaker. Alternatively, early environmental stress may underlie autonomic underarousal and hyporeactivity in antisocial individuals. Finally, it is possible that biofeedback, in combination with a multimodal treatment program, may be one benign intervention technique that may increase arousal and reduce aggression in underaroused antisocial children.

Cellular mechanisms of brain energy metabolism: relevance to functional brain imaging and to neurodegenerative disorders

Abstract: Astrocyte end-feet surround intraparenchymal microvessels and represent therefore the first cellular barrier for glucose entering the brain. As such, they are a likely site of prevalent glucose uptake. Astrocytic processes are also wrapped around synaptic contacts, implying that they are ideally positioned to sense and be functionally coupled to increased synaptic activity. We have recently demonstrated that glutamate, the main excitatory neurotransmitter, stimulates in a concentration-dependent manner 2-DG uptake and phosphorylation by astrocytes in primary culture. The effect is not receptor-mediated but rather proceeds via one of the recently cloned glutamate transporter. The mechanism involves an activation of the Na+/K+ ATPase. Concomitant to the stimulation of glucose uptake, glutamate causes a concentration-dependent increase in lactate efflux. These observations suggest that glutamate uptake is coupled to aerobic glycolysis in astrocytes. In addition, since glutamate release occurs following the modality-specific activation of a brain region, the glutamate-evoked uptake of glucose into astrocytes provides a simple mechanism to couple neuronal activity to energy metabolism. These data also suggest that modality-specific activation visualized using 2DG-based autoradiography or PET may primarily reflect glutamate-mediated uptake of 2DG into astrocytes.

History of Oral Tolerance and Mucosal Immunitya

Abstract: Mucosal immunity depends on antigen stimulation in specialized lymphoepithelial structures such as the Peyer's patches. Although these inductive compartments were discovered more than 300 years ago, their functional role has become clear only over the last few decades. Research on homing of primed lymphoid cells to the intestinal mucosa began with animal experimentation in the 1960s and 1970s and has recently been brought to the molecular level. The major effector substance of mucosal immunity is secretory IgA (SIgA). The first evidence for its local antibody activity was obtained in humans in 1922, but its unique properties were not defined until the mid-1960s. Several models were subsequently proposed for selective external transport of IgA involving the secretory component (SC). In the early 1970s SC was suggested to act as a transmembrane polymeric Ig receptor common for dimeric IgA and pentameric IgM; this transport mechanism has now been confirmed by detailed studies at the level of cellular/molecular biology. Although SIgA antibodies performing immune exclusion are the main goal for exploitation of the mucosal immune system by oral vaccination, little is known about the precise mechanisms for induction of mucosal immunity against soluble proteins and chemicals. A peripheral immunosuppressive effect of oral immunization with such substances was apparently exploited by ancient people, and "oral tolerance" has since 1910 been subjected to numerous feeding experiments in rodents. The basis for the whole phenomenon appears to be intact epithelial barrier. Mucosal induction of suppression may in the future be exploited not only to modulate autoimmune diseases through the gut but also to prevent the development of IgE-mediated allergy and other untoward immune reactions by way of the respiratory tract.

Amyloid fibril toxicity in Alzheimer's disease and diabetes.

Abstract: Several lines of evidence suggest that amyloid deposition in the brain contributes to neuronal degeneration in Alzheimer's disease (AD). In the AD brain, diffuse plaques composed mostly of amorphous beta amyloid (Am-beta A) are inert, whereas compact plaques composed of beta amyloid fibrils (Fib-beta A) are associated with neurodegenerative changes. The effects of these two types of amyloid were tested on primary rat hippocampal neurons. Fib-beta A induced the formation of dystrophic neurites and caused neuronal cell death, whereas Am-beta A was not toxic. In addition, Fib-beta A caused synapse loss in the remaining viable neurons, whereas Am-beta A did not significantly affect synapse number. We also examined the effects of amylin, the primary constituent of the amyloid fibrils that form in the pancreas in adult-onset diabetes. Amylin was toxic to rat and human insulin-producing islet cells in the concentration range of fibril formation. The relative toxic potencies of amylin peptides of different species correlated with their fibril-forming capacity. Soluble amylin was not toxic. The amyloid fibril-binding dye Congo red inhibited the toxicity of both beta A and amylin. Congo red afforded protection against toxicity by a dual mechanism. When present during the phase of fibril polymerization, Congo red could inhibit fibril formation from some peptides. When added to preformed fibrils, Congo red bound to fibrils rendering them nontoxic. These results suggest that fibril formation is necessary for both beta A and amylin toxicity. Congo red appears to be a general inhibitor of amyloid fibril toxicity and may therefore be a useful prototype for drugs targeted to the amyloid pathology of AD and adult-onset diabetes.

Oral Tolerance in Experimental Autoimmune Encephalomyelitis

Abstract: In work performed by a number of laboratories, it has become quite clear that the oral administration of autoantigens exerts a profoundly suppressive effect on the development and long-term clinical course of autoimmune disease. Specific peptide sequences derived from the autoantigens are similarly suppressive. An interesting sidelight to emerge from specificity studies is that oral administration of a self-protein or peptide sequence (i.e., rat MBP peptide administered to a rat) is markedly less tolerogenic than oral administration of a non-self or even closely related sequence (guinea pig MBP peptide administered to a rat). The dose of oral antigen is now known to play a critical role in determination of the mechanism of oral tolerance, with low doses of antigen causing active suppression with concomitant release of TGFbeta1. Studies outlined here suggest that oral administration of higher antigen doses (e.g., 20 mg MBP to rats or mice) results in deletion of specific antigen-reactive T lymphocytes. This conclusion stems from the fact that injections of IL-2 could not reverse high-dose tolerance while reversing low-dose oral tolerance. Moreover, feeding MBP to MBP-TCR transgenic mice caused trafficking of transgenic cells to the intestine followed by a profound depletion of transgene-positive cells and reduction in proliferative function in all peripheral lymphoid organs. Oral tolerance has proven to be of therapeutic benefit in other animal models of autoimmune disease as well, including uveitis, collagen-induced arthritis, adjuvant arthritis, thyroiditis, myasthenia gravis, and diabetes. Initial human trials in multiple sclerosis, rheumatoid arthritis, and uveitis show promising results.

Interleukin‐12 Production by Dendritic Cells

Abstract: Recent studies have demonstrated that the treatment of mice with anti-gp39 antibodies impairs T-cell functions in the murine collagen type II-induced arthritis model, in acute semi-allogenic graft-versus-host disease, and in the allo-specific CTL-reaction, that is, reactions that are believed to be mediated by Th1-type T cells. On the other hand, the administration of anti-gp39 antibody did not influence Th2 T-cells responses, suggesting that CD40-CD40L interactions are more crucial for Th1 than Th2 T-cell development. Recent studies also demonstrate that dendritic cells (DC) are capable of driving a Th1 T-cell response that is mediated by IL-12. In addition, stimulation of CD40 on human monocytes results in IL-12 production, suggesting that activated T cells expressing CD40L may directly induce the production of IL-12 by antigen-presenting cells, thus allowing for the generation of a Th1 T-cell response in the absence of intracellular pathogens. We investigated whether the CD40-CD40L interaction was important in the production of IL-12 by DCs in an in vitro system that allowed precise control of cytokine concentrations. Initially we showed that FACS-purified mouse spleen DCs produce high amounts of IL-12 p40 in response to CD40 crosslinking by CD40L-expressing fibroblasts. We then demonstrate that DCs also produce IL-12 p40 in a more physiologic system using purified DCs pulsed with ovalbumin (OVA) and then cultured with LECAM-1hi T cells from ovalbumin T-cell receptor transgenic mice. Finally, we show that IL-10 has a potent capacity to shut down CD40-induced IL-12 p40 secretion; and, in addition, IL-4 partially inhibits CD40-induced IL-12 p40 secretion and enhances IL-10-mediated inhibition in an additive fashion. We also investigated the in vivo relevance of this interaction in an experimental model for a Th1-mediated disease, the hapten reagent (TNBS)-induced colitis. The administration of anti-gp39 (CD40L) antibodies during the induction phase of the Th1 response completely prevented IFN-gamma production by CD4 T cells from the intestinal lamina propria and also the clinical and histological evidence of disease. In further studies we showed that the prevention of disease activity was due to an inhibition of IL-12 secretion. Thus, the injection of recombinant IL12 p75 heterodimer into TNBS + anti-gp39-treated mice reversed the effect of anti-gp39 and resulted in severe disease activity. In conclusion, these findings suggest that DCs produce IL-12 in response to CD40 signaling, that a mechanism by which IL-4 may induce Th2 development is by acting with IL-10 to inhibit IL-12 production by DCs, and that the CD40L-CD40 interaction is crucial for the IL-12-dependent priming of Th1 T cells in vivo.

Oxidative Stress and Parkinson's Disease

Abstract: The underlying mechanism of cell death in substantia nigra of Parkinson's disease patients remains unknown. Biochemical changes occurring in substantia nigra in Parkinson's disease (increased iron levels, inhibition of complex I activity and decreased reduced glutathione levels; GSH) suggest that oxidative stress and free radical species may be involved. In particular, a decrease in GSH levels may be an early component of the process, since this also occurs in incidental Lewy body disease (presymptomatic Parkinson's disease). GSH is lost only from the substantia nigra in Parkinson's disease and this does not occur in other neurodegenerative disorders of the basal ganglia. GSH loss appears to be global throughout the substantia nigra and not localized to either the glia or neuronal elements. The activity of enzymes involved in the glutathione cycle are normal with the exception of gamma-glutamyltranspeptidase, the activity of which is increased. This could result in increased removal and degradation of glutathione from cells. Depletion of GSH in rat using L-buthionine-[S, R]-sulfoxamine (BSO) potentiates 6-hydroxydopamine (6-OHDA) toxicity but does not in itself produce degeneration of the nigrostriatal pathway. Oxidative stress may be a potentially important factor in the degeneration of the substantia nigra in Parkinson's disease and warrants further investigation into its role in this process.

Role of Complement, Chemokines, & Regulatory Cytokines in Acute Lung Injury

Abstract: The roles of complement, proinflammatory cytokines and regulatory cytokines in lung inflammatory injury are becoming defined. Like the proinflammatory cytokines (TNF alpha and IL-1), complement activation products (C5a and/or the membrane attack complex, C5b-9) can directly activate endothelial cells to cause upregulation of adhesion molecules (P-selectin) or can function in a synergistic manner with TNF alpha to cause enhanced upregulation of ICAM-1 and E-selectin. The beta chemokine, MIP-1 alpha, appears to function in vivo as an autocrine activator, enhancing TNF alpha production by pulmonary macrophages, which, in turn, enhances the inflammatory response. Finally, IL-4 and IL-10 have strong regulatory effects by suppressing in vivo production of TNF alpha. There is now compelling evidence to suggest that, in IgG immune-complex-induced lung inflammation in rats, endogenous IL-10 is produced and regulates the intensity of the inflammatory response. Blocking of endogenous IL-10 substantially increases lung TNF alpha production, the recruitment of neutrophils, and the intensity of lung inflammatory injury. Accordingly, the network of cytokines carefully regulates lung inflammatory responses.

Interleukin-12 antagonist activity of mouse interleukin-12 p40 homodimer in vitro and in vivo.

Abstract: Mo(p40)2 is a potent IL-12 antagonist that interacts strongly with the beta 1 subunit of the IL-12R to block binding of moIL-12 to the high-affinity mouse IL-12R. Mo(p40)2, alone or in synergy with the 2B5 mAb specific for the moIL-12 heterodimer, blocked IL-12-induced responses in vitro, Mo(p40)2 was thus used alone or with 2B5 mAb to examine the role of IL-12 in vivo, Mo(p40)2 caused a dose-dependent inhibition of both the rise in serum IFN-gamma levels in mice injected with endotoxin and the Th1-like response to immunization with KLH. Treatment with mo(p40)2 plus 2B5 anti-moIL-12 mAb also suppressed DTH responses to methylated bovine serum albumin but not specific allogeneic CTL responses in vivo. In each of these models, responses seen in mice treated with mo(p40)2 +/- 2B5 anti-moIL-12 mAb were similar to those observed in IL-12 knockout mice. Thus, mo(p40)2 can act as a potent IL-12 antagonist in vivo, as well as in vitro, and is currently being used to investigate the role of IL-12 in the pathogenesis of some Th1-associated autoimmune disorders in mice.

Peroxisome Proliferator-activated Receptors: Stuctures and Function

Abstract: We have been attempting to elucidate the molecular mechanisms through which peroxisome proliferators exert their pleiotropic effects, with particular emphasis on understanding why humans appear unresponsive to these compounds. There is a wealth of data to implicate the peroxisome proliferator-activated receptor alpha (PPAR alpha) in mediating these effects in rodent species; PPAR alpha is expressed in tissues that show physiological changes in response to PPs, is transcriptionally activated in vitro by a variety of PPs, and it has been recently demonstrated that mice lacking this receptor are refractory to the effects of clofibrate and Wy-14,643, at least in the short term. It is conceivable that differences in PPAR alpha between responsive rodent and unresponsive human subjects may provide the key to understanding the basis of this species variation in response, and with this in mind we have been studying the biology of PPAR alpha in humans and looking at interindividual variation. There is already published evidence, albeit on only two sequences, for structural and functional polymorphism in human PPAR alphas. We have extended these findings, and shown that: There is considerable variation in hPPAR alpha cDNAs obtained from different individuals, both at the gross structural level (lack of a coding exon) and of a more subtle nature (single base changes leading to amino acid substitutions). One such cDNA, the sequence of which differs at only three amino acids from that published, encodes a receptor that is incapable of transcriptional activation by potent PPs. The degree to which hPPAR alpha transcripts are expressed in human livers can vary by up to an order of magnitude between individuals. The tissue-specific expression profile of PPAR alpha in humans is very different from that in rat and mouse. In particular, the human liver contains generally low levels of PPAR alpha in contrast to the responsive rodents, in which potent PPs cause liver tumors. Taken together, these data suggest first that human and rodent PPAR alphas differ according to a number of molecular and biochemical criteria, and secondly that there is a degree of interindividual variation in PPAR alpha structure and function. Studies are ongoing to clarify this further, but human polymorphism may go some way towards explaining the apparent paradox that active PPAR alpha receptors can be isolated from an "unresponsive" species.

Incidence and prevalence of abdominal aortic aneurysms, estimated by necropsy studies and population screening by ultrasound

Abstract: Incidence and prevalence of abdominal aortic aneurysms, estimated by necropsy studies and population screening by ultrasound.

Structure, microtubule interactions, and phosphorylation of tau protein.

Abstract: This paper summarizes recent structural and functional studies on tau protein, its interactions with microtubules, its self-assembly into paired helical filaments (PHF)-like fibers, and its modification by phosphorylation. The structure of tau in solution resembles that of a random coil. Both tau and Alzheimer PHFs have very little secondary structure, making it improbable that the assembly of tau into PHFs is based on interacting beta sheets. Tau's binding to microtubules can be described by a "jaws" effect. The domain containing the repeats binds very weakly, while the flanking regions (jaws) bind strongly, even without the repeats. However, only the combination of flanking regions and repeats makes binding productive in terms of microtubule nucleation and assembly. Although the majority of Alzheimer-like phosphorylation sites are outside the repeats they have only a weak influence on binding, whereas the phosphorylation at Ser262 inside the repeats inhibits binding and makes microtubules dynamically unstable. This site can be phosphorylated by kinases present in brain tissue, and it is uniquely phosphorylated in Alzheimer brain.

IL‐12‐Deficient Mice Are Defective but Not Devoid of Type 1 Cytokine Responses

Abstract: Interleukin-12 (IL-12) has been described as a pivotal molecule in the immune response based in part on its ability to influence the differentiation of T helper (Th) cells into a type 1 (Th1) phenotype. This event is crucial in that appropriate differentiation of naive T cells can determine susceptibility or resistance to given pathogens by influencing the balance between cellular and humoral immunity. In order to further delineate the role of IL-12 in the immune response, we generated mice deficient for this cytokine. IL-12 knockout mice were viable, fully fertile, and displayed no obvious developmental abnormalities. Upon immunological analysis, these mice demonstrated an impaired ability to effect a Th1 response as well as an impaired ability to produce interferon-gamma in response to endotoxin in vivo. These data establish an essential role for IL-12 in the generation of optimal Th1 responses in vivo, but weak responses can occur independently of IL-12.

Na-Ca exchange and Ca fluxes during contraction and relaxation in mammalian ventricular muscle.

Abstract: There are four cellular Ca transport systems which compete to remove Ca from the myoplasm in mammalian ventricular myocytes. These are 1) the SR Ca-ATPase, 2) the sarcolemmal Na-Ca exchange, 3) the sarcolemmal Ca-ATPase and 4) the mitochondrial Ca uniporter. Using multiple experimental approaches we have evaluated the dynamic interaction of these systems during the normal cardiac contraction-relaxation cycle. The SR Ca-ATPase and Na-Ca exchange are clearly the most important, quantitatively; however, the relative roles vary in a species-dependent manner. In particular, the SR is much more strongly dominant in rat ventricular myocytes, where approximately 92% of Ca removal is via SR Ca-ATPase and only 7% via Na-Ca exchange during a twitch. In other species (rabbit, ferret, cat, and guinea pig) the balance is more in the range of 70% SR CA-ATPase and 25-30% Na-Ca exchange. Ferret ventricular myocytes also exhibit an unusually strong sarcolemmal Ca-ATPase. During the steady state the same amount of Ca must leave the cell as enters over a cardiac cycle. This implies that 25-30% of the Ca required to activate contraction must enter the cell, and experiments demonstrate that this amount of Ca may be supplied by the L-type Ca current.

Bioproduction of human enzymes in transgenic tobacco.

Abstract: Transgenic plants have significant potential in the bioproduction of complex human therapeutic proteins due to ease of genetic manipulation, lack of potential contamination with human pathogens, conservation of eukaryotic cell machinery mediating protein modification, and low cost of biomass production. Tobacco has been used as our initial transgenic system because Agrobacterium-mediated transformation is highly efficient, prolific seed production greatly facilitates biomass scale-up, and development of new "health-positive" uses for tobacco has significant regional support. We have targeted bioproduction of complex recombinant human proteins with commercial potential as human pharmaceuticals. Human protein C (hPC), a highly processed serum protease of the coagulation/anticoagulation cascade, was produced at low levels in transgenic tobacco leaves. Analogous to its processing in mammalian systems, tobacco-synthesized hPC appears to undergo multiple proteolytic cleavages, disulfide bond formation, and N-linked glycosylation. Although tobacco-derived hPC has not yet been tested for all posttranslational modifications or for enzymatic (anticlotting) activity, these results are promising and suggest considerable conservation of protein processing machinery between plants and animals. CropTech researchers have also produced the human lysosomal enzyme glucocerebrosidase (hGC) in transgenic tobacco. This glycoprotein has significant commercial potential as replacement therapy in patients with Gaucher's disease. Regular intravenous administration of modified glucocerebrosidase, derived from human placentae or CHO cells, has proven highly effective in reducing disease manifestations in patients with Gaucher's disease. However, the enzyme is expensive (dubbed the "world's most expensive drug" by the media), making it a dramatic model for evaluating the potential of plants to provide a safe, low-cost source of bioactive human enzymes. Transgenic tobacco plants were generated that contained the human glucocerebrosidase cDNA under the control of an inducible plant promoter. hGC expression was demonstrated in plant extracts by enzyme activity assay and immunologic cross-reactivity with anti-hGC antibodies. Tobacco-synthesized hGC comigrates with human placental-derived hGC during electrophoretic separations, is glycosylated, and, most significantly, is enzymatically active. Although expression levels vary depending on transformant and induction protocol, hGC production of > 1 mg/g fresh weight of leaf tissue has been attained in crude extracts. Our studies provide strong support for the utilization of tobacco for high-level production of active hGC for purification and eventual therapeutic use at potentially much reduced costs. Furthermore, this technology should be directly adaptable to the production of a variety of other complex human proteins of biologic and pharmaceutical interest.

Endogenous Vertebrate Antibiotics

Abstract: Although newly recognized, endogenous cystine-stabilized beta-sheet antimicrobial peptides have ancient origins. These peptides can arm circulating phagocytes and cells of the gastrointestinal, respiratory, and genitourinary tracts to resist invasion by bacteria, mycobacteria, fungi, and enveloped viruses. Defensins and protegrin-like peptides are likely to play a considerable role in innate immunity and may provide molecular templates that can be used to generate novel antibiotics for topical and systemic use.