This study investigated rice production status, rice consumption characteristics, and rice import and export trends in sub-Saharan Africa for researchers and policy makers on rice production in Africa and to suggest key strategy to improve rice self-sufficiency in Africa. In recent years, sub-Saharan Africa has seen an increasing number of food security conflicts because of climate change. The ultimate solution is to increase their food productivity and self-sufficiency in their countries. Rice is very important for poverty reduction in Africa because of its availability and affordability, making it accessible to the poor in Africa as a staple food. The total area of rice production in sub-Saharan Africa has nearly doubled from 7 million ha in 2000 to 13 million ha in 2020, and rice demand is also on the rise. However, the climate change and extreme weather events have led to greater variability in rice productivity, and international rice prices have increased continuously, making it increasingly difficult to improve Africa's rice self-sufficiency. In order to increase rice production and improve self-sufficiency in Africa, there are many challenges, such as irrigation facilities, improving soil quality, and supplying pesticides and fertilizers, but the most important is to develop and disseminate new rice varieties suitable for the African region. This will require not only breeding appropriate varieties for Africa's climate and soil, but also selecting proper varieties that meet the preferences of Africans. Additionally, an infrastructure system from production, cultivation, harvesting and storage to processing for the appropriate rice varieties should be aligned at the same time.

Previously, we reported that the osmolarity conditions in the satellite region were affected CpG DNA methylation status while Pre-1 sequence was not affected CpG DNA methylation in pNT blastocyst stage. This study was conducted to investigate the DNA methylation status of repeat sequences in pig nuclear transfer (pNT) embryos produced under different osmolarity culture conditions. Control group of pNT embryos was cultured in PZM-3 for six days. Other two treatment groups of pNT embryos were cultured in modified PZM-3 with 138 mM NaCl or 0.05 M sucrose (mPZM-3, 320 mOsmol) for two days, and then cultured in PZM-3 (270 mOsmol) for four days. The DNA methylation status of the Pre-1 sequences in blastocysts was characterized using a bisulfite-sequencing method. Intriguingly, in the present study, we found the unique DNA methylation at several non-CpG sequences at the Pre-1 sequences in all groups. The non-CpG methylation was hypermethylated in all three groups, including in vivo group (86.90% of PZM- 3; 83.87% of NaCl; 84.82% of sucrose; 90.94% of in vivo embryos). To determine whether certain non-CpG methylated sites were preferentially methylated, we also investigated the methylation degree of CpA, CpT and CpC. Excepting in vivo group, preference of methylation was CpT>CpC>CpA in all three groups investigated. These results indicate that DNA methylation of Pre-1 sequences was hypermethylated in CpG as well as non-CpG site, regardless modification of osmolarity in a culture media.

Osmolarity of culture media is one of the most important factors affecting in vitro development. This study was conducted to investigate the DNA methylation status of Pre-1 and satellite sequence in pig nuclear transfer (pNT) embryos produced under different osmolarity culture conditions. Control group of pNT embryos was cultured in PZM-3 for six days. Other two treatment groups of pNT embryos were cultured in modified PZM-3 with 138 mM NaCl or 0.05M sucrose (mPZM-3, 320 mOsmol) for two days, and then cultured in PZM-3 (270 mOsmol) for four days. Previous our studies have reported that pNT embryos cultured in both hypertonic media showed significantly higher blastocyst formation rate than that of control. The DNA methylation status of the satellite sequences in blastocyst was characterized using bisulfite-sequencing technology. The satellite region had a similar methylation pattern of in vivo blastocyst among two culture groups excepting the control group. Each level of methylation is that the satellite DNA moderately methylated (43.10% of PZM-3; 56.12% of NaCl; 55.06% of sucrose; 60.00% of in vivo embryos). As a result of the sequence of PRE-1, CpG methylation pattern was similar to three groups, including in vivo group. In case of the satellite DNA region, the osmolarity conditions were affected CpG DNA methylation status while PRE-1 sequence was not affected CpG DNA methylation in pNT blastocyst stage. These results indicate that the modification of osmolarity in a culture media may influence to spatially change of DNA methylation of repetitive sequence for pNT embryo development.