The production of domestic protein for feed in Poland is insufficient. The import of feed raw materials, especially soybean, which is genetically modified (GM) is necessity. In 2016, Poland imported about 2 million tonnes of GM soybean. In Poland was introduced a ban for using and production of GM feed (Law – animal feed from 2006). This ban has already been suspended few times, mainly due to the fact, that the complete replacement of imported GM soybean meal with other components was impossible. The Minister of Agriculture and Rural Development appointed “Team for alternative sources of protein”, responsible for finding solutions that will impact on reducing imports and will increase the share of domestic sources of protein in animal feed. To achieve this aim research are needed to indicate plants and their possibilities for using. The aim of the article is to analyse selected feed components such as: soybean and rapeseed meal, sunflower meal and oilcakes. This analysis concerns the area of cultivation of soybean, rapeseed and sunflower, purchase costs of meals and oilcakes, properties of these components and foreign trade in Poland.

The future of food security in Africa is being severely threatened due to an exponential increase in population, which is almost three times the increase of food production. Maize production is constrained by stem borers which cause significant yield losses. Yield losses can be further compounded by higher temperatures due to climate changes, which are expected to increase the population of maize stem borers. While several methods have been employed in stem borer management, there is still significant damage caused by maize stem borers. This necessitates better control methods including the adoption of recent biotechnological advancement in RNA interference (RNAi) technology. This review highlights evidence of an increase in the stem borer population as well as the foreseen decline in maize production worldwide due to the effects of climatic changes. Furthermore, we have drawn attention to improved methods that have been used to control stem borers in maize production as well as a reluctant acceptance of traditional biotechnology in Africa. Finally, we suggest the application of alternative RNA interference techniques to breed maize for efficient pest control in order to achieve food security, improve nutrition and promote sustainable maize production.

Considerable climate changes have been observed in the last 50 years – warming in every spatial scale (global, continental, regional and local), changes in atmospheric precipitation and several weather extremes, shrinking of cryosphere and sea level rise. The warming since the mid-20th century has predominantly been due to greenhouse gas emissions from human activities, in particular the combustion of fossil fuels, farming and other changes in land use. The paper presents the aspects of impact of climate change for farming and food security and the impact of farming for climate change in Polish and global scale. Agriculture holds a meaningful potential of reduction of greenhouse gas emissions and of carbon sequestration. It will be necessary to manage optimally advantageous changes and effectively adapt to adverse changes.

Today, ensuring energy security is becoming increasingly important. It has been proven that agricultural crops are currently the dominant feedstock for the production of biofuels and first-generation biofuels dominate both in Ukraine and around the world and can potentially pose a threat to food security. The research aims to analyze the state of food security in Ukraine in order to estimate the economic basis for the use of surplus food crops for biofuel production for substantiating the required areas for growing energy crops in the volumes that could ensure balance between the food and energy use of crops. An analysis of food security of Ukraine showed that the agricultural sector provides the population with most of the necessary food products, but it is advisable to modernize the food supply standards. It has been proven that crops that can be used for the production of first-generation biofuels in Ukraine are produced in sufficient quantities to ensure food security, and they are exported without compromising the food security of the state and export potential.
As calculated, Ukraine can use about 11–12 million hectares of arable land for growing energy crops with their subsequent processing into biofuels. It has been proven that in the future in Ukraine, it is recommended to develop the production of biofuels (biogas and solid biofuels) from crop and livestock waste, as well as organic waste from processing enterprises. This would not pose a threat to food security and would address a number of environmental issues related to waste disposal. Today, under the condition of war in Ukraine, food security and energy independence are priority issues and energy diversity, including the production and consumption of biofuels, is a top factor for further development.

The specificities of the sowing and harvesting campaign of 2022–2023 in Ukraine and its impact on the world energy and food market in the conditions of the full-scale invasion of Ukraine by the Russian Federation are analyzed in this paper. The purpose of the study is to determine the role of Ukraine in ensuring energy and global food security, to analyse the situation regarding the possibility of conducting a sowing and harvesting campaign in Ukraine in the conditions of hostilities and to provide recommendations on preserving the potential of Ukraine in meeting the energy and food needs of Ukraine and other countries. The provided analysis of data of the Food and Agriculture Organization (FAO), the State Customs Service and the State Statistics Service of Ukraine has confirmed the role of Ukraine in ensuring energy and food safety of many countries in the Middle East and North Africa, which are the main importers of agricultural products from Ukraine. It has been found that the 2022–2023 sowing and harvesting campaign in Ukraine is facing a number of problems, including: military operations over a large area, which makes it impossible to conduct agrotechnical activities in a timely manner; a lack of seed material due to its systematic destruction by the Russian military; problems with the supply of fuel and lubricants (systematic shelling and destruction of oil bases throughout Ukraine); problems with the supply of fertilizers; bombing wheat fields and food warehouses; blocking Ukrainian sea ports; mobilization of a significant part of the population in the ranks of the Armed Forces of Ukraine; logistics problems. The study proposes recommendations to preserve the potential for meeting energy and food needs in Ukraine and for countries importing agricultural products from Ukraine.

Global warming and climate change are some of the most widely discussed topics in today's society, and they are of considerable importance to agriculture globally. Climate change directly affects agricultural production. On the other hand, the agricultural sector is inherently sensitive to climate conditions, and this has made the agricultural sector one of the most vulnerable sectors to the effects of global climate change. Rising CO2 levels in the atmosphere, increased temperature, and altering precipitation patterns all substantially influence agricultural insect pests and agricultural productivity. Climate change has a number of implications for insect pests. They can lead to a decreased biological control effectiveness, particularly natural enemies, increased incidence of insect-transmitted plant diseases, increased risk of migratory pest invasion, altered interspecific interaction, altered synchrony between plants and pests, increase in the number of generations, increased overwintering survival, and increase in geographic distribution. As a consequence, agricultural economic losses are a real possibility, as is a threat to human food and nutrition security. Global warming will necessitate sustainable management techniques to cope with the altering state of pests, as it is a primary driver of pest population dynamics. Future studies on the impacts of climate change on agricultural insect pests might be prioritized in several ways. Enhanced integrated pest control strategies, the use of modelling prediction tools, and climate and pest population monitoring are only a few examples.