Method to Direct the Reciprocal Interactions Between the Ureteric Bud and the Metanephric Mesenchyme
SUMMARY
Researchers at UCLA have developed an approach to construct an embryonic kidney in vitro for the treatment of end stage renal disease.
BACKGROUND
End stage renal disease (ESRD) is a fatal illness characterized by the permanent loss of kidney function that affects 1.6 million people worldwide. Every year, approximately $32 billion dollars is spent on treating ESRD patients. Currently, the preferred treatment for ESRD is kidney transplantation, which is limited by the shortage of donor organs and complications due to rejection and immunosuppression. Furthermore, the use of dialysis, the second treatment option for ESRD, presents a tremendous financial burden and is associated with poor quality of life and a high morbidity rate. Regenerative medicine is working towards developing novel methods to overcome these limitations through in vitro kidney organogenesis. However, the structural complexity of the adult kidney imposes an insurmountable hurdle against any attempt to construct a functional adult kidney by conventional tissue engineering strategies. Therefore, there is an urgent need for alternative novel treatments for ESRD patients.
INNOVATION
UCLA researchers in the laboratory of Dr. Yanagawa have developed a method to construct an embryonic kidney in vitro for the treatment of ESRD. The present invention utilizes developmental engineering principles to generate kidney progenitor cells to construct and control kidney development on the cellular level. Proper formation of the kidney requires the three main cell types, the ureteric bud (UB), the metanephric mesenchymal (MM) cells, and the stromal (SM) cells, to interact in a highly organized and specific manner. Although previous research has demonstrated that UB and MM cells are capable of forming primitive kidney structures in vitro, the method is not sufficient to create a functional organ due to the inability to control the interaction between these three cell types.
The present invention circumvents these difficulties by providing a platform whereby the interaction of UB, MM and SM cells is tightly regulated. The controlled environment mimics the developmental process in the embryo and thereby generates an organized embryonic kidney in vitro. The in vitro generated embryonic kidneys will be implanted back to the patient where they will develop into adult kidneys. This will help to relieve that donor shortage with shortened waiting time, and since these kidneys consist of patient tissue, the risk of tissue rejection is practically non-existent, which subsequently reduces the need for life-long immunosuppressive therapy.
APPLICATIONS
- Construction of an embryonic kidney in vitro for kidney transplantation.
- Embryonic kidney can be used to study kidney development, drug toxicity and the effect of pharmacological substances on kidney function
ADVANTAGES
- The present invention supports the self-organization potential of the renal progenitor cells and allows the generation of embryonic kidney tissue in vitro with the potential to drain urine and thus functions as an excretory organ.
- Due to the high similarity of the developmental process of the kidney in mammals, the present invention can be applied to generate embryonic kidneys in vitro in other mammal species, such as mouse, rat, sheep, pig, apes and human.
STATE OF DEVELOPMENT
Renal development has been observed from the cultured cells in vitro. The generated structure can be implanted into an animal for further development.
RELATED MATERIALS
Nishikawa, M., Yanagawa, N., Kojima, N., Yuri, S., Hauser, P. V., Jo, O. D., Yanagawa, N. Stepwise renal lineage differentiation of mouse embryonic stem cells tracing in vivo development, 2012.