I'm assuming that there is independence between each of the constestants. Let $p_i$ denote the probability that the $i$'th contestant beats the Original. Then $ P(\text{none of cont1-cont4 wins})=\prod_{i=1}^4 (1-p_i)\approx 0.4153 $ and therefore $ P(\text{any of cont1-cont4 wins})=1-P(\text{none of cont1-cont4 wins})\approx 0.5847. $
It's just elementary probability theory. Let $A_i$ denote the event that the $i$'th contestant wins, i.e. $P(A_1)=0.269$, $P(A_2)=0.213$ and so on. Then the complement $A_i^c$ is the event that the $i$'th contestant does not win and $P(A_i^c)=1-P(A_i)$ for all $i=1,\ldots,5$ (elementary property of a probability measure). Now $ P(\text{none of cont1-cont4 wins})=P\left(\;\bigcap_{i=1}^4 A_i^c\right)\stackrel{\rm indep.}{=} \prod_{i=1}^4 P(A_i^c)=\prod_{i=1}^4 \big(1-P(A_i)\big)\approx 0.4153, $ where we have used the definition of independent sets. At last we use that the complementary set of $\{\text{any of cont1-cont4 wins}\}$ is exactly the set $\{\text{none of cont1-cont4 wins}\}$.