Mutation of a conserved asparagine in the I-like domain promotes constitutively active integrins alphaLbeta2 and alphaIIbbeta3

The leukocyte beta2 integrins are heterodimeric adhesion receptors required for a functional immune system. Many leukocyte adhesion deficiency-1 (LAD-1) mutations disrupt the expression and function of beta2 integrins. Herein, we further characterized the LAD-1 mutation N329S in the beta2 inserted (I)-like domain. This mutation converted alphaLbeta2 from a resting into a high affinity conformer because alphaLbeta2N329S transfectants adhered avidly to ligand intercellular adhesion molecule (ICAM)-3 in the absence of additional activating agent. An extended open conformation is adopted by alphaLbeta2N329S because of its reactivity with the beta2 activation reporter monoclonal antibodies MEM148 and KIM127. A corresponding mutation in beta3 generated constitutively active alphaIIbbeta3 that adhered to fibrinogen. This Asn is conserved in all human beta subunits, and it resides before the last helix of the I-like domain, which is known to be important in activation signal propagation. By mutagenesis studies and review of existing integrin structures, we conjectured that this conserved Asn may have a primary role in shaping the I-like domain by stabilizing the conformation of the alpha7 helix and the beta6-alpha7 loop in the I-like domain.     

Vibrational spectroscopy of the oxygen-evolving complex and of manganese model compounds

A number of molecularly specific models for the oxygen-evolving complex in photosystem II (PSII) and of manganese-substrate water intermediates that may occur in this process have been proposed recently. We summarize this work briefly. Fourier transform infrared techniques have emerged as fruitful tools to study the molecular structures of Y(Z) and the manganese complex. We discuss recent work in which mid-IR (1000-2000 cm(-1)) methods have been used in this effort. The low-frequency IR region (<1000 cm(-1)) has been more difficult to access for technical reasons, but good progress has been made in overcoming these obstacles. We update recent low-frequency work on PSII and then present a detailed summary of relevant manganese model compounds that will be of importance in understanding the emerging biological data.     

Troglitazone inhibits growth of MCF-7 breast carcinoma cells by targeting G1 cell cycle regulators

Peroxisome proliferator activated receptor gamma (PPARgamma) is a member of the nuclear receptor superfamily. Ligand activation of PPARgamma has been shown to cause growth arrest in several human tumor cell types, but the underlying molecular mechanism has not been elucidated. We report here that the PPARgamma ligand troglitazone (TRO) inhibited MCF-7 cell proliferation by blocking events critical for G1 --> S progression. Flow cytometry demonstrated that TRO at 20 microM increased the percentage of cells in G1 from 51 to 69% after 24 h. Accumulation of cells in G1 was accompanied by an attenuation of Rb protein phosphorylation associated with decreased CDK4 and CDK2 activities. Inhibition of CDK activity by TRO correlates with decreased protein levels for several G1 regulators of Rb phosphorylation (cyclin D1, and CDKs 2, 4, and 6). Overexpression of cyclin D1 partially rescued MCF-7 cells from TRO-mediated G1 arrest. Targeting of G1 regulatory proteins, particularly cyclin D1, and the resulting induction of G1 arrest by TRO may provide a novel antiproliferative therapy for human breast cancer.     

Antagonistic effects of TGFbeta1 and BMP-6 on skin keratinocyte differentiation

Several members of the transforming growth factor beta (TGFbeta) superfamily are expressed in the developing murine epidermis. Among these are TGFbeta1, which is found in the basal layer, and bone morphogenetic protein (BMP)-6, located in the suprabasal layers. Although the role of TGFbeta in cell growth has been studied extensively, little is known about the effects of these factors on keratinocyte differentiation. This study demonstrates that BMP-6 acts to positively regulate the differentiation of primary skin keratinocytes grown in culture. In contrast, TGFbeta1 antagonizes keratinocyte differentiation blocking the upregulation of keratin markers by BMP-6. We show that the effects of BMP-6 on expression of keratin 1 (K1), a marker of differentiation, requires signaling through the Smad pathway. In addition, regulation of K1 levels by BMP-6 is modulated by the SEK signaling pathway. This suggests that regulation of keratinocyte differentiation by BMP-6 involves multiple signaling systems.     

Rubella virus E2 signal peptide is required for perinuclear localization of capsid protein and virus assembly

The rubella virus (RV) structural proteins capsid, E2, and E1 are synthesized as a polyprotein precursor. The signal peptide that initiates translocation of E2 into the lumen of the endoplasmic reticulum remains attached to the carboxy terminus of the capsid protein after cleavage by signal peptidase. Among togaviruses, this feature is unique to RV. The E2 signal peptide has previously been shown to function as a membrane anchor for the capsid protein. In the present study, we demonstrate that this domain is required for RV glycoprotein-dependent localization of the capsid protein to the juxtanuclear region and subsequent virus assembly at the Golgi complex.     

Agonist-specific regulation of delta-opioid receptor trafficking by G protein-coupled receptor kinase and beta-arrestin

Opioid receptors mediate multiple biological functions through their interaction with endogenous opioid peptides as well as opioid alkaloids including morphine and etorphine. Previously we have reported that the ability of distinct opioid agonists to differentially regulate mu-opioid receptor (mu OR) responsiveness is related to their ability to promote G protein-coupled receptor kinase (GRK)-dependent phosphorylation of the receptor (1). In the present study, we further examined the role of GRK and beta-arrestin in agonist-specific regulation of the delta-opioid receptor (delta OR). While both etorphine and morphine effectively activate the delta OR, only etorphine triggers robust delta OR phosphorylation followed by plasma membrane translocation of beta-arrestin and receptor internalization. In contrast, morphine is unable to either elicit delta OR phosphorylation or stimulate beta-arrestin translocation, correlating with its inability to cause delta OR internalization. Unlike for the mu OR, overexpression of GRK2 results in neither the enhancement of delta OR sequestration nor the rescue of delta OR-mediated beta-arrestin translocation. Therefore, our findings not only point to the existence of marked differences in the ability of different opioid agonists to promote delta OR phosphorylation by GRK and binding to beta-arrestin, but also demonstrate differences in the regulation of two opioid receptor subtypes. These observations may have important implications for our understanding of the distinct ability of various opioids in inducing opioid tolerance and addiction.     

Mutational analysis of the structure and function of opioid receptors

The cloning of the opioid receptors allows the investigation of receptor domains involved in the peptidic and nonpeptidic ligand interaction and activation of the opioid receptors. Receptor chimera studies and mutational analysis of the primary sequences of the opioid receptors have provided insights into the structural domains required for the ligand recognition and receptor activation. In the current review, we examine the current reports on the possible involvement of extracellular domains and transmembrane domains in the high-affinity binding of peptidic and nonpeptidic ligands to the opioid receptor. The structural requirement for the receptors' selectivity toward different ligands is discussed. The receptor domains involved in the activation and subsequent cellular regulation of the receptors' activities as determined by mutational analysis will also be discussed. Finally, the validity of the conclusions based on single amino acid mutations is examined.