IMPACT OF CLIMATE FACTORS ON YIELD AND QUALITY OF VINE VARIETY CABERNET SAUVIGNON IN PODGORICA WINE GROWING REGION SUMMARY The influence of climatic factors on grape yield, grape cluster weight, sugar and acidity content in stum in variety Cabernet Sauvignon was measured in period from 2011 to 2013 at the experimental field of Biotechnical Faculty in Podgorica. The study was conducted in the vineyard of the Biotechnical Faculty in Podgorica in the stage of full grape maturity

The influence of climatic factors on grape yield, grape cluster weight, sugar and acidity content in stum in variety Cabernet Sauvignon was measured in period from 2011 to 2013 at the experimental field of Biotechnical Faculty in Podgorica. The study was conducted in the vineyard of the Biotechnical Faculty in Podgorica in the stage of full grape maturity. The highest grape yield as well as the cluster weight were measured in 2012 (1.2 kg/m 2 and 125 g respectively), while the lowest values were measured in 2013 0.88 kg/m 2 and 92 g. Highest sugar content in stum was measured in 2011, and lowest in 2013. The highest acid content was measured in 2013 (6.50 g/l) as a result of heavy rainfall during the growing season, especially in August and September. Differences between the studied parameters were statistically significant. The results showed that the yield and quality of grapes were in direct relation with the weather conditions in certain years of experiments.


INTRODUCTION
Due to favourable soil and climatic conditions Podgorica wine growing region was always considered an area very suitable for vine growing. However, the climatic parameters are significantly fluctuating leading to deterioration of usual weather conditions in recent years. There are many indicators confirming that the climate in this wine growing region is changing rapidly: the number of days with tropical temperature is rising, periods of drought are longer and more frequent especially during the summer months, the number of days without rain is increasing, but also the intensity of precipitation. Precipitation is particularly intense during the winter months and often has flood character (Micev, 2014).
Climate change is taking place in every part of the globe in a greater or lesser extent -from the equator to the poles (Gearheard et al., 2010). The consequences of climate change are evident in many viticulture areas of the world and predominantly manifested in the changes occurring in the phenophases of vines, as well as the harvest date (Jones et al., 2007). Although Montenegro, as a small geographical area, does not affect the global climate change, it does increasingly suffer from its negative impact, and consequently vine production as well.
Numerous studies worldwide predict that extreme future weather conditions will be more frequent, and negative impact on agricultural production will be more noticeable. All listed above impose a constant need for research of impact of changing climate on agro-technological and economical characteristics of the dominantly cultivated varieties of vine in Montenegro, and therefore the variety Cabernet Sauvignon as well, which is one of the leading vine varieties for the production of high quality red wines. However, it should always be considered that in addition to agro ecological conditions (relief, exposure, temperature sums, radiation, physical and mineral properties of soil), agro biological, economical and technological properties of grape vines are significantly affected by the level of applied ampelotechnics, the type of rootstock, growth form, the pruning technique and many others. (Brighenti et al., 2010;Van Leeuwen and Seguin, 1994).
The aim of this study is to evaluate the impact of major climatic parameters on the yield and quality of grape variety Cabernet Sauvignon, especially during the vegetation season in Podgorica wine growing region.

MATERIAL AND METHODS
The study of the influence of climatic factors on the yield and quality of grape variety Cabernet Sauvignon was conducted in 2011, 2012 and 2013. The study was performed at the experimental field of the Biotechnical Faculty in Podgorica. Experimental vineyard was planted in 2005 with the planting distance of 2.5 m between rows and 1 m within rows. Growing form of vine is double horizontal cordon with trunk height of about 80 cm. Mixed pruning was applied. Tests were carried out on 30 vines, that is, three repetitions with 10 vines.
During the three-year study grape yield was examined (kg/m2), cluster weight (g), sugar (%) and acid content (g/l) in stum. Yield was obtained by measuring the harvested grapes and calculating grape weight per m2, cluster weight was determined from the ratio of the yield of ten vines and number of grape clusters. The sugar content in the grape juice was determined with areometrically (Oeschle must balance), and proportion of the total acid in the grape juice by neutralization of acids and their salts with n/10 NaOH solution using bromothymol blue indicator.
In the analysis of climate in Lješkopolje, data from weather stations in Podgorica were used. Statistical analysis of the results was performed using analysis of variance and LSD test.

RESULTS AND DISCUSSION
Yield quantity and quality is heavily influenced by climate and the prevailing meteorological conditions in production regions (Mirošević and Karoglan -Kontić, 2008 Table 1 clearly shows that air temperature in Podgorica wine growing region is in constant growth, especially in the summer period. If we analyze climate anomalies, expressed through the differences in the values of climate parameters between the multi-year average  and the period from 2011 to 2013, we come to the conclusion that the climate in this wine-growing region is rapidly changing. Compared to long-term averages, average annual air temperature in 2011 was 0.7°C higher than the long term average, in 2013 0.5°C, while in 2012 was at the level of long-term averages. The mean temperature in vegetation period in the three-year average was 23°C which is 1°C more than in the multi-year average. In the second research year, medium temperature in vegetation period was 23.4°C, and was slightly higher than in the first year (23.1°C) and significantly higher than in the third year in which the mean temperature during the vegetation period was 22.4°C. The average sum of active temperatures during the vegetation period for the period 1985-2010 was 4715.3°C, while in the studied period was significantly higher -4916.1°C. In the studied period, the highest temperature sum in vegetation period was in 2012 (5007.6°C). Table 2 shows that in the period May -Aug -July -August in 2012 was measured significantly higher maximum air temperature compared to the same period in 2011 and 2013. In other months, the maximum air temperatures were at the same level. In 2012, in the period May -September, was also measured the highest minimum air temperature (tab. 3).
Tab. 3. Absolute minimum air temperatures Year Months  Year  min  I  II  III  IV  V  VI  VII VIII IX X XI XII 2011 -3.0 -3.1 -2.3 4.7 9.9 16.7 14.9 16.9 17.5 2.9 0.3 -2.6 -3.1 2012 -5.5 -5.7 2.5 0.4 10.7 14.9 19.6 17.7 10.9 7.2 4 -5.5 -5.7 2013 -2.3 -2.3 -0.6 8.6 10.0 11.3 16.9 18.5 11.1 1.7 -1 -3.3 -3.3 Jovović et al. (2015) state that the number of tropical days and duration of the warm tropical waves have significantly increased in Podgorica. They further alleged that 59% of June, 87% of July and 86% of August days had a tropical character, and that 15% of the days during June, 40% of the days in July and 45% of the days during August had high tropical temperatures (maximum temperature reaches and passes 35 o C). Also, the average number of summer days (maximum temperature during the day reaches and exceeds 25°C), has increased from 129 to 145 days.
Tab The results given in Table 4 show that in Podgorica wine growing region mean annual rainfall for the period 1985-2010 was 1777.5 mm, while in the period studied (2011-2013) was lower and was 1683.1 mm. These data show that in precipitation amounts between the observed periods there were no significant changes, but the changes were significant in the precipitation regimepronounced rainy and drought periods during the year. In 2011, the annual amount of rainfall was only 894.9 l/m 2 , or 882.6 l/m 2 less than long-term averages. In the second year, the annual amount of precipitation (1763.6 mm) was at the level of multi-year average, while in the third year it was significantly higher and was 2,391 l/m 2 .
When analysing rainfall in the vegetation period (tab. 4) it is clear that in 2011 precipitation level of only 309.8 l/ m2 was significantly lower than in 2012 and 2013 in which during the vegetation period was measured 911.6 l/ m2 and 914.5 l/ m2, respectively. It is interesting to note that in 2013, for the first three months, it was measured record amount of rain -1090 l/ m2. Most of the rainfall in this year fell in March -518.6 mm; three and a half times more than the usual rainfall for this month. Since the measuring of rainfall exists in Montenegro (for 64 years) it has not happened that this much rain falls in March (Micev, 2015).
The average amount of precipitation during the vegetation period from 2011 to 2013 was 711.8 l/m2. Although in the studied period, compared to the multi-year average (649.5 l/ m2), was registered more rainfall, this does not mean that the vines in these years were sufficiently provided with water. Namely, in 2011 and 2012, the distribution of rainfall was quite unfavourable, with a strong deficit in the warmest period of the year.
Grape yield per area unit, as an absolute indicator of productivity of varieties, is conditioned by a number of factors. Among the more important are biological characteristic of the variety and environmental conditions in the studied years. The results in Table 5 show that the yield of grapes was in accordance with the weather conditions in studied years. The lowest yield of grapes (0.83 kg/m2) was measured in 2013, with highest precipitation, both on annual basis, and during the vegetation period. This year there was a very high intensity of plant diseases, which, along with noticeable reduction in yield and increased use of chemicals, significantly increased the production costs. The highest yield was measured in 2012 (1.20 kg/m2), while in 2011 it was 0.96 kg/ m2. Statistical analysis of data showed that the yield of grapes in 2012 was significantly higher compared to 2013, and less significant compared to 2011. The difference in the yield of grapes between the first and the third year of study did not have the statistical significance for any level of probability. Yields in all years of study have been at the level for the variety Cabernet Sauvignon cited by other authors (Pejović, 1996;Burić, 1995;Cindrić, 2000;Mirošević, 2008 etc.).

Tab. 5. The yield and quality of grape variety Cabernet Sauvignon
Year ( kg/m 2 ) Grape cluster weight ( The results of the study of average cluster weight of variety Cabernet Sauvignon are given in Table 5. Analyzing the average values in years of study it can be noted that in 2012 cluster weight was significantly higher than in 2013 and less significant in comparison to 2011. The higher cluster weight in first two years of the experiment (125 and 104 g respectively) was due to significantly more favourable environmental conditions in those years, particularly temperature. During these years, the average air temperatures in the vegetation period were significantly higher compared to 2013. The results are consistent with the results reported by Popović et al, 2013, which stated that the cluster weight of variety Vranac in Podgorica wine growing region was higher in climatically favourable years. The average weight of clusters in this research was at the level of values that the variety Cabernet Sauvignon has in the same agroecological conditions as stated by Pejović et al., 1996and Pajović et al., 2009. According to Božinović (2010 the average cluster weight of variety Cabernet Sauvignon is ranging from 90 to 120 g, which also supports the results obtained. Trough influence on physiological processes of vine, ecological potential of wine growing regions significantly affects the quality of grapes, primarily the content of sugars and acids. The amount of sugar in grapes, apart from the variety, greatly depends on the degree of maturity and health status of grapes, as well as of the climatic conditions in the ripening stage of grapes (Ranković -Vasić, 2011).
Based on the results shown in Table 5, the highest sugar content of the grapes was measured in 2011 (24,10%) and the lowest in 2013 (21.00%). This is the direct consequence of the variation in weather conditions that prevailed in years of performing experiments. In 2013, with the lowest mean air temperature in vegetation period and the highest amount of precipitation in the vegetation period, the sugar content in stum was lowest. Similar results were reported by Vukosavljević et al. (2011) who measured higher sugar content in years with higher mean temperatures in vegetation period. The importance and impact of growing conditions on the yield and quality of grapes indicate Santalucia et al. (2007) and Mota et al. (2008) as well.
Acids in stum are an important indicator of the quality of grapes, as taste and harmony of the wine produced depends on their presence. The results of three-year research showed that the average content of acids in stum was satisfying and typical for the variety Cabernet Sauvignon grown in the agro ecological conditions of Podgorica wine growing region. The highest content of acids was measured in 2013 -6.50 g/l, as a result of higher precipitation during the vegetation period, especially in August and September (123.1 and 178.4 l/m 2 respectively). Such conditions have significantly affected the quality of the grapes, primarily the acid content. Statistical analysis of data revealed that in 2013 the acid content was significantly higher compared to the other years studied. These results are consistent with the results of Pejović et al., (1996) and Pajović et al., (2014). However, Mirošević et al., (2008 reported higher values for the content of acids in grape variety Cabernet Sauvignon (7-9 g/l), which was probably a consequence of different agro-ecological conditions in which they conducted their research.

CONCLUSIONS
Based on the research done, it can be concluded: The average yield of grapes in the three-year period was 10 t/ha, sugar content 22.7%, and the acid content 6.10 g/l. Yield and cluster weight were lowest in 2013, which is explained by the large amount of rainfall during the vine vegetation period.
Very high sugar content was measured in 2011 and 2012 (24.1 and 23.0% respectively) as a result of higher average air temperature in the vine vegetation period.
The highest acid content was measured in 2013 as a result of heavy rainfall in August and September.
The results of these studies indicate significant impact of climatic factors on the amount and quality of yields of this variety. However, despite the increasing influence of climate change, there are still very favourable agroecological conditions for growing Cabernet Sauvignon in Podgorica wine growing region.