Rab11 and Actin Cytoskeleton Participate in Giardia lamblia Encystation, Guiding the Specific Vesicles to the Cyst Wall

The encystation process is crucial for survival and transmission of Giardia lamblia to new hosts. During this process, vesicular trafficking and the cytoskeleton play important roles. In eukaryotic cells, intracellular transport is regulated by proteins, including Rab-GTPases and SNAREs, which regulate vesicle formation along with recognition of and binding to the target membrane. Cytoskeletal structures are also involved in these processes. In this study, we demonstrate the participation of Rab11 in the transport of encystation-specific vesicles (ESVs). Additionally, we demonstrate that disruption of actin microfilaments affects ESVs transport. The modification of actin dynamics was also correlated with a reduction in rab11 and cwp1 expression. Furthermore, down-regulation of rab11 mRNA by a specific hammerhead ribozyme caused nonspecific localization of CWP1. We thus provide new information about the molecular machinery that regulates Giardia lamblia encystation. Given our findings, Rab11 and actin may be useful targets to block Giardia encystation

Inhibition of the hammerhead ribozyme cleavage reaction by site-specific binding of Tb.

Terbium(III) [Tb(III)] was shown to inhibit the hammerhead ribozyme by competing with a single magnesium(II) ion. X-ray crystallography revealed that the Tb(III) ion binds to a site adjacent to an essential guanosine in the catalytic core of the ribozyme, approximately 10 angstroms from the cleavage site. Synthetic modifications near this binding site yielded an RNA substrate that was resistant to Tb(III) binding and capable of being cleaved, even in the presence of up to 20 micromolar Tb(III). It is suggested that the magnesium(II) ion thought to bind at this site may act as a switch, affecting the conformational changes required to achieve the transition stat

Effects of magnesium ions on two EMCV IRES key activity fragments

Using NMR magnetization transfer from water and ammonia-catalyzed exchange of the imino protons, changes have been monitored in base-pair kinetics induced by Mg2 +  in two key activity fragments r(CACCUGGCGACAGGUG) and r(GGCCAAAAGCC) of the encephalomyocarditis virus internal ribosome entry site. For r(CACCUGGCGACAGGUG), the addition of Mg2 +  reveals two types of base-pairs: r(U545·A) and r(G546·C), in the first category, have lifetimes only slightly higher in the presence of Mg2 + , whereas their dissociation constants are substantially reduced. This behavior has been termed proximal. The base-pairs r(G553·C) and r(G554·C), in the second category, have lifetimes substantially higher in the presence of Mg2 + , whereas their dissociation constants remain almost constant. This behavior has been termed distal. Mg2 +  has a specific effect on r(CACCUGGCGACAGGUG), the magnitude of which is progressively modulated from the proximal region of the 16-mer towards its distal region. For r(GGCCAAAAGCC), an intermediate behavior is found for base-pairs r(G565·C) and r(G572·C). Their lifetimes are slightly higher in the presence of Mg2 +  and their dissociation constants are significantly lower, a behavior resembling that of the 16-mer proximal region. These results indicate that Mg2 +  diffusively moves around r(GGCCAAAAGCC)