Transition of Vibrio cholerae through a natural host induces resistance to environmental changes

The pandemic-related strains of Vibrio cholerae are known to cause diarrheal disease in animal hosts. These bacteria must overcome rapid changes in their environment, such as the transition from fresh water to the gastrointestinal system of their host. To study the morphological adjustments during environmental transitions, we used zebrafish as a natural host. Using a combination of fluorescent light microscopy, cryogenic electron tomography and serial block face scanning electron microscopy, we studied the structural changes that occur during the infection cycle. We show that the transition from an artificial nutrient-rich environment to a nutrient-poor environment has a dramatic impact on the cell shape, most notably membrane dehiscence. In contrast, excreted bacteria from the host retain a uniform distance between the membranes as well as their vibrioid shape. Inside the intestine, V. cholerae cells predominantly colonized the anterior to mid-gut, forming micro-colonies associated with the microvilli as well as within the lumen. The cells retained their vibrioid shape but changed their cell-length depending on their localization. Our results demonstrate dynamic changes in morphological characteristics of V. cholerae during the transition between the different environments, and we propose that these structural changes are critical for the pathogen’s ability to colonize host tissues

Transition of Vibrio cholerae through a natural host induces resistance to environmental changes

The pandemic-related strains of Vibrio cholerae are known to cause diarrheal disease in animal hosts. These bacteria must overcome rapid changes in their environment, such as the transition from fresh water to the gastrointestinal system of their host. To study the morphological adjustments during environmental transitions, we used zebrafish as a natural host. Using a combination of fluorescent light microscopy, cryogenic electron tomography and serial block face scanning electron microscopy, we studied the structural changes that occur during the infection cycle. We show that the transition from an artificial nutrient-rich environment to a nutrient-poor environment has a dramatic impact on the cell shape, most notably membrane dehiscence. In contrast, excreted bacteria from the host retain a uniform distance between the membranes as well as their vibrioid shape. Inside the intestine, V. cholerae cells predominantly colonized the anterior to mid-gut, forming micro-colonies associated with the microvilli as well as within the lumen. The cells retained their vibrioid shape but changed their cell-length depending on their localization. Our results demonstrate dynamic changes in morphological characteristics of V. cholerae during the transition between the different environments, and we propose that these structural changes are critical for the pathogen’s ability to colonize host tissues

Transition of Vibrio cholerae through a natural host induces resistance to environmental changes

The pandemic-related strains of Vibrio cholerae are known to cause diarrheal disease in animal hosts. These bacteria must overcome rapid changes in their environment, such as the transition from fresh water to the gastrointestinal system of their host. To study the morphological adjustments during environmental transitions, we used zebrafish as a natural host. Using a combination of fluorescent light microscopy, cryogenic electron tomography and serial block face scanning electron microscopy, we studied the structural changes that occur during the infection cycle. We show that the transition from an artificial nutrient-rich environment to a nutrient-poor environment has a dramatic impact on the cell shape, most notably membrane dehiscence. In contrast, excreted bacteria from the host retain a uniform distance between the membranes as well as their vibrioid shape. Inside the intestine, V. cholerae cells predominantly colonized the anterior to mid-gut, forming micro-colonies associated with the microvilli as well as within the lumen. The cells retained their vibrioid shape but changed their cell-length depending on their localization. Our results demonstrate dynamic changes in morphological characteristics of V. cholerae during the transition between the different environments, and we propose that these structural changes are critical for the pathogen’s ability to colonize host tissues

An Experimental Flow-Controlled Multicast ATM Switch

BNR and Harvard have jointly designed an experimental ATM switch called CreditSwitch with sixteen 622-Mbps ports. Expected to be operational in early 1995, the switch will support credit-based flow control and full-speed multicast. This paper gives a brief overview of the switch architecture and its design goals. 1. Introduction ATM switches will need a new level of sophistication to handle a high-volume mix of bursty data and multimedia traffic under, respectively, ABR ("Available Bit Rate") and CBR ("Constant Bit Rate) or VBR ("Variable Bit Rate") services. Such traffic will require switch support for scheduling, policing, congestion control, and multicast. Not only should a switch support these features, but it should support them in a cost-effective manner. Harvard and Bell-Northern Research (BNR) have designed an experimental ATM switch with sixteen 622-Mbps (Mega bit per second) ports to study new switching methods to meet these requirements. As of October 1994, all the board ..