A bacterial effector targets Mad2L2, an APC inhibitor, to modulate host cell cycling.

The gut epithelium self-renews every several days, providing an important innate defense system that limits bacterial colonization. Nevertheless, many bacterial pathogens, including Shigella, efficiently colonize the intestinal epithelium. Here, we show that the Shigella effector IpaB, when delivered into epithelial cells, causes cell-cycle arrest by targeting Mad2L2, an anaphase-promoting complex/cyclosome (APC) inhibitor. Cyclin B1 ubiquitination assays revealed that APC undergoes unscheduled activation due to IpaB interaction with the APC inhibitor Mad2L2. Synchronized HeLa cells infected with Shigella failed to accumulate Cyclin B1, Cdc20, and Plk1, causing cell-cycle arrest at the G2/M phase in an IpaB/Mad2L2-dependent manner. IpaB/Mad2L2-dependent cell-cycle arrest by Shigella infection was also demonstrated in rabbit intestinal crypt progenitors, and the IpaB-mediated arrest contributed to efficient colonization of the host cells. These results strongly indicate that Shigella employ special tactics to influence epithelial renewal in order to promote bacterial colonization of intestinal epithelium.

Selecting effective siRNA target sequences for mammalian genes.

Short interfering RNA (siRNA) has been widely used for studying gene functions in mammalian cells but varies markedly in its gene-silencing efficacy in mammalian genes. The recently reported guidelines for selecting effective siRNA target sequences are not always useful for selecting highly effective siRNA sequences for many other mammalian genes because there are only a few consistencies among them. Hypothesizing that the positional nucleotide occurrence trends play an important role in effective gene-silencing, we examined 361 effective siRNA sequences from 227 different mammalian cDNAs in the literature and found got several nucleotide features different from the ones used in the previous guidelines. Here we first explain the problems concerning the previous guidelines from the qualitative and quantitative points of view. Then after clarifying the requirements for effective siRNA designs, we describe a new method based on a gene degradation measure defined by positional features of specific significant nucleotides. Testing the method on human cyclin B1 confirmed that it selected highly effective gene-silencing sequences and also indicated that it would be useful for other genes. It will therefore be useful for selecting new siRNA target sequences for mammalian genes.

An effective method for selecting siRNA target sequences in mammalian cells.

RNA interference is a gene-silencing phenomenon triggered by dsRNA (double-stranded RNA) and has been widely used for studying gene functions. The short interfering RNA (siRNA) responsible for RNA interference, however, varies markedly in its gene-silencing efficacy. Because this efficacy depends on the selected target sequences, we developed an effective selection method based on the gene degradation measure (priority score) defined by positional features of individual nucleotides. We tested this method experimentally by using it to select new siRNA target sequences in the homo sapiens cyclin B1 gene (CCNB1) and confirmed that it selected highly effective gene-silencing sequences. The proposed method will therefore be useful for selecting new siRNA target sequences in mammalian cells.